Methods And Systems For Growing Plants Using Silicate-Based Substrates, Cultivation Of Enhanced Photosynthetic Productivity And Photosafening By Utilization Of Exogenous Glycopyranosides For Endogenous Glycopyranosyl-Protein Derivatives, And Formulations, Processes And Systems For The Same

ABSTRACT

Methods for promoting plant growth based on novel photosafening treatment regimes with glycopyranosides including glycopyranosylglycopyranosides, and aryl-α-D-glycopyranosides, and more specifically, with one or more compounds comprising terminal mannosyl-triose, optionally in the presence of light enhanced by one or more light reflecting and/or refracting members such as silicon-based substrates. Furthermore, chemical synthesis processes for the above compounds are disclosed for general application to plants. Silicate microbeads of the like are distributed over the ground or substrate in which roots of a plant are supported and planted, beneath and around a plant in a manner that light is refracted or reflected toward the phylloplane.

This application is a divisional of U.S. patent application Ser. No.14/359,455 filed May 20, 2014, which is a 371 of PCT/US2012/065768 filedNov. 19, 2012, which claims priority of U.S. Provisional ApplicationSer. No. 61/561,992 filed Nov. 21, 2011, and U.S. ProvisionalApplication Ser. No. 61/677,515 filed Jul. 31, 2012, the disclosures ofwhich are hereby incorporated by reference.

FIELD

The embodiments disclosed herein relate to methods, formulations anddevices for treating plants and more specifically to methods for growingplants in the presence of light reflecting and/or refracting memberssuch as silicon-based substrates with the option of photosafening byapplication of formulations comprising glycopyranosides and derivatives.

BACKGROUND

The growth of plants is dependent efficiency photosynthesis, therefore,light is required; however, light intensity is reduced by pollutants,particulates, and shading. In regions of high latitudes, particularlyduring seasons of short days and inclement weather, low light intensityand short periods of exposure to sunlight limit the growth of greenplants. Moreover, in greenhouses, light is lost in the course oftransmission through membranes, artificial electrical illumination andprotective housings. Under conventional row crop cultivation situations,light lost to absorption by the ground itself. When cultivated underelectrical illumination, photosynthetic efficiency is of utmostimportance under the relatively low light intensities that must bemaintained to sustain affordability. There is a profound need toredistribute the light in a manner that shines light up to the plantand, thereby, adding to the available light for photosynthesis.Furthermore, at certain times, too much light, to the point of lightsaturation, may result in photoinhibition and photorespiration. Thesephysiological events that run counter to photosynthesis under lightsaturative environmental conditions have long been known to effectivelyreduce and sap productivity. Therefore a concomitant requirement forphotosafening the inhibitory effects of light saturation should be met.

The growth of plants is also dependent on the availability of glucose,especially in cells, but the timely and direct release of stored glucoseand the substrates for intracellular displacement of glucose fromstorage have not been previously defined. Furthermore, the involvementof α-D-glycopyranose in metabolic pathways of pyranoses also has notbeen completely defined.

Generally, substituted-α-D-glycopyranosides have been typically regardedas inactivated in a plant and therefore, incapable of eliciting anyplant growth activity by exogeneously making them available to theplant. However, contrary to prior teachings, the methods andformulations of the embodiments disclosed herein apply substitutedglycopyranosides to plants. Once these selected glycopyranosides enterthe cell, they act as exogenous substrates for displacement of glucose,having recognized that most substituted-α-D-glycopyranosides displaceglucose from storage in glycoproteins. Glucose is the energy store inany plant and the application of α-D-glycopyranosides to allocate carboninto the largest displacement from storage glycoproteins may open cropsto the proportionate enhancement of yield potential.

It is an object of embodiments disclosed herein to provide methods fortreating and cultivating plants with redistributed light for enhancingplant growth. It is a further object of embodiments disclosed herein toprovide the option for methods and formulations for photosafeninq plantsby applying a formulation comprising one or more glycopyranosides,preferably, α-D-glycopyranose compounds, to the plants that may beexposed to light saturation resulting from extra light refracted orreflected from silicon-based substrates.

It is a further object of embodiments disclosed herein to providemethods and formulations for treating plants and photosafening fromsaturated light environments by applying a formulation comprising one ormore glycopyranosides, preferably substituted-α-D-glycopyranosides, andmost preferably alkyl-α-D-mannopyranoside; and salts, derivatives andcombinations thereof, to plants.

It is a still further object of embodiments disclosed herein to providemethods and formulations for treating plants and enhancing growth byapplying a formulation of one or more synthetic components ofglycopyranosides to plants, such as the highly preferredelectron-donating aryl-α-D-glycopyranosides, of which a preferredexample is aminophenyl-α-D-mannopyranoside.

It is a further object of embodiments disclosed herein to providemethods and formulations for treating plants and enhancing plant growthby applying a formulation of one or moresubstituted-α-D-glycopyranosides to green plants.

It is yet a further object of embodiments disclosed herein to providemethods and formulations for treating plants and enhancing plant growthby applying one or more compounds selected from a group consisting ofglycopyranosides, salts and derivatives thereof and combinationsthereof, to plants, particularly green plants, as photosafeners to lightsaturation when they are cultivated in the presence of a solid mediumthat will redirect light for enhanced photosynthetic efficiency.

Yet another object of embodiments disclosed herein is to provideformulations for endogenous biochemical processing of one or morecompounds selected from a group consisting of highly substitutedα-D-glycopyranosyl-glycoproteins resulting from exogenous applicationswith the aforementioned glycopyranosidic compounds, salts andderivatives thereof and combinations thereof, to plants.

It is a further object of embodiments disclosed herein to providemethods for the activation of the aforementioned glycopyranosidiccompounds, with the divalent cations of calcium and manganese.

It is yet a further object of embodiments disclosed herein to providemethods for the chemical synthesis of one or more compounds selectedfrom a group consisting of highly substituted α-D-glycopyranosides overthe catalysts, Mn, Ca and K.

It is a further embodiment to exploit the alkaline qualities of sodalimesilicate microbeads to sequester the climate change gas, carbon dioxide.The culture of plants in microbeads was achieved by development of asystem for maintaining pH-appropriate environments with continuous flowthrough of acidic plant nutrients, including elevated levels of carbondioxide gas.

It is a further object of embodiments disclosed herein to providemethods for the activation of the aforementioned glycopyranosidiccompounds, with the divalent cations of calcium and manganese.

These and other objects will become apparent from the description hereintogether with any drawings and claims.

SUMMARY

Light reflecting and/or refracting members such as glass microbeadsenhance the intensity of photosynthetically active radiation (PAR). Whenlocated near foliage, these members direct PAR light to the phylloplaneadding to the light. Through co-application of glycoside formulationsdisclosed herein, plants efficiently utilize light from the lightreflecting and/or refracting members, such as microbeads. Plants may becultivated in the light reflecting and/or refracting members by methodsdisclosed herein that overcome alkalinity and light saturation problems;however, the major application of the light reflecting and/or refractingmembers will be in greenhouses and fields to enhance light intensity inenvironments of light limitation. Light may be from any source, eithersolar or artificial. Distribution of a thin layer beneath and/or onplants will shine light up to foliage. Also, incorporation of lightreflecting and/or refracting members into substrates of, for example,greenhouse walls and support surfaces will become light sources.

An example of field crop utilization is to incorporate glass microbeadsinto the long rows of plastic sheets placed under strawberrycultivation. Microbeads may be applied over an adhesive to coat theplastic or incorporated into the sheets during manufacture.

The methods and formulations of embodiments disclosed herein weredeveloped on the basis that glycopyranosides competitively displaceglucose from storage such that glucose may contribute to growth inplants. Specificity resulting in carbon partitioning in plants isdetermined by the binding of glycoproteins with multiple glycopyranosylsresulting in the formation of glycopyranosyl-glycoprotein tetramers.Disclosed are methods for promoting plant growth based on novelphotosafening treatment regimes with glycopyranosides includingglycopyranosylglycopyranosides, and aryl-α-D-glycopyranosides, and morespecifically, one or more compounds comprising electron donators, suchas amines, optionally in the presence of silicon-based substrates.Furthermore, chemical synthesis processes for the above compounds aredisclosed for general application to plants.

In accordance with certain embodiments, light reflecting and/orrefracting members such as silicate microbeads or the like aredistributed over the ground or substrate in which roots of a plant aresupported and planted, therein, beneath and around a plant in a mannerthat light is refracted or reflected toward the phylloplane;furthermore, a plant may be cultivated in a bed volume of lightreflecting and/or refracting members such as refractive microbeads as asupport medium. Light reflecting and/or refracting members such assilicate microbeads may, alternatively, be distributed about thefoliage, above, below, and around the ground surfaces, or toinfrastructural surfaces of plant cultivation buildings at other sides.

In accordance with certain embodiments, refractive qualities ofmicrobeads may be exploited to improve distribution of light from theground or substrate surfaces, and from the shoot of a plant, up tofoliage, especially during early stages of growth until the canopy fillsin. Similarly, when compared against common soils, the light intensitiesrecorded above thin layers of refractive microbeads were 20% to 80%higher. Moreover, coated microbeads, such as with dyes, paints,anti-reflectants, and UV-absorbents may be applied beneficially todirect specific wavelengths of light up to the phylloplane. Microbeadsmay also be coated with beneficial microbes such as probiotics, fungi,and bacteria; and accompanied by nutrient coatings, as a vehicle ofdispersal. Microbeads may also be distributed over substrates, walls,walkways, countertops, tables, paper, plastic sheets and strips inlocations that benefit from additional light.

In addition to serving as solid support media, microbeads refract light,thus, enhancing photosynthetic efficiency. The boost to light intensity(I) from microbeads has the potential to improve productivity, but whenincreased to saturation, photorespiration may influence the outcome.Therefore, methods for cultivation of plants in microbeads withappropriate treatments were developed.

In further accordance with certain embodiments, the alkaline qualitiesof sodalime silicate microbeads may be exploited to improve distributionand sequestration of carbon dioxide by the hydroponic support medium.The culture of plants in microbeads was achieved by development of asystem for maintaining pH-appropriate environments with continuous flowthrough of acidic plant nutrients, including elevated levels of carbondioxide gas.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a photograph of Crocus was wholly plucked out from cultivationin microbeads moistened with nutrients or test solutions in accordancewith certain embodiments; the image shows the result of dipping theroots in water, where the roots were cleared of the beads, allowingunobstructed photodocumentation of intact roots;

FIG. 2(A) is a photograph of vegetative propagation of cuttings ofcoleus in 500 μm nmd microbeads, in accordance with certain embodiments;

FIG. 2(B) is photograph of plant roots that have been gently pulled outof silicate microbeads showing intact microstructure, evidence of nodamage;

FIG. 3 is a photograph of corn cultured in 700 μm nmd silicate beadswith buffered nutrient solution of the present invention. The control,left, showed a 5 cm taproot. The plant treated with indoxylglycopyranoside, right, in accordance with certain embodiments,exhibited a 7 cm taproot;

FIG. 4(A) is a photograph of paperwhite narcissus, cultured 700 μm nmdsilicate beads in buffered nutrient solution of the present invention,in accordance with certain embodiments;

FIG. 4(B) is a photograph of a control showing plant roots, left, havingless volume than bulbs treated with indoxyl glycopyranoside, right;

FIG. 4(c) is an image showing a densely spaced culture of five bulbspermitted by the measured abundance of buffered nutrients that flowthrough the silicate support medium.

FIG. 5 is a photograph of the variety “Ninsei” in 300 μm nmd silicatemicrobeads in accordance with certain embodiments;

FIG. 6 is a graph of radish root growth rate after various foliarapplications of formulations in accordance with certain embodiments.

FIG. 7 is a photograph of radish sprouts after treatment (right) with500 μM methyl-α-D-mannopyranoside (MeM), compared to the NutrientControl (left);

FIG. 8 is a graph of radish sprouts growth rate after immersion informulations in accordance with certain embodiments;

FIG. 9 is a graph of radish sprouts growth rate after foliar applicationof formulations in accordance with certain embodiments;

FIG. 10 is a photograph of radish sprouts after treatment (right) with10 μM p-amino-phenyl-α-D-mannopyranoside (APM), compared to the NutrientControl (left);

FIGS. 11A and 11B are schematic diagrams of light refracted frommicrobeads;

FIG. 12 is a photograph of an aura above a layer of μBeads shown throughpolarizing filters;

FIG. 13 is a diagram of the Lectin Cycle for Competitive Displacement ofGlucose;

FIG. 14 is a diagram of a microbead embedded in a substrate inaccordance with certain embodiments;

FIG. 15 is a photograph of a plastic flat for plants with a layer ofmicrobeads bonded to the top rims in accordance with certainembodiments;

FIG. 16 is a photograph of a glazed ceramic planter with a layer ofmicrobeads bonded to the top rim in accordance with certain embodiments;and

FIG. 17 is a photograph of a greenhouse polyethylene membrane withmicrobeads adhered to part of the infrastructural material in accordancewith certain embodiments.

DETAILED DESCRIPTION

The methods and formulations disclosed herein are designed to enhancephotosynthetic productivity and, moreover, to treat plants with aphotosafener. Enhancement of photosynthetic efficiency is achieved byapplying one or more light reflecting and/or refracting members, such assilicates, to the surface below plants, to the shoot, or by cultivatingplants in them in an arrangement that light is refracted and reflectedtoward the phylloplane. In conjunction with the event of lightsaturation, proactive treatments with photosafeners are disclosed forcontinuous plant growth enhancement as generally achieved by formulatingone or more glycopyranosides. The formulation preferably may be appliedin a dry or liquid form directly to the plants through application to amoistened solid medium as a photosafener that ameliorates photosynthesisunder environmental stress of light saturation that would otherwiseresult in photorespiration or photoinhibition.

Specifically, the photosafener formulations generally provide the plantwith glycopyranosides and synthetic precursor components to enhancegrowth, wherein the components may include, but are not limited to,variously preferred substituted glycopyranosides such as, for example,aminophenylmannopyranoside, aminophenylxyloside,aminophenylfructofuranoside, glycopyranosylglycopyranoside,tetraacetylmannopyranose; and indoxyl glycopyranosides which maystimulate plant growth through photosafening by application of compoundssuch as indole carboxylate, indoxyl acetyl glycopyranoside, isatin,isatan, isatoxime, indirubin and nitrobenzaldehydeindogenide.

In accordance with certain embodiments, a method for treating plants andfor consequential enhancement of plant growth comprises the step ofapplying an effective amount of one or more compounds selected from agroup consisting of glycopyranosides, preferably, α-D-glycopyranosides,and most preferably, aryl-α-D-glycopyranosides; salts and derivativesand combinations, thereof to the plant. The treatments are mosteffective in the presence of light saturation that may occur in thepresence of one or more light reflecting and/or refracting members, suchas silicon-based substrates. The effective amount is preferably anamount that enhances plant growth, and is preferably between about 0.1ppm to about 5000 ppm. One or more highly preferred aryl-compounds maycomprise electron-donator arylglycopyranosides such as4-aminophenyl-α-D-mannopyranoside, wherein an effective amountpreferably comprises aminophenyl-α-D-mannopyranoside in an amountbetween about 0.01 ppm to 1000 ppm concentration. In addition oralternatively, one or more of these compounds may comprise donatingaryl-pentosides, such as aminophenyl-α-D-xyloside, derivatives, isomersand salts, thereof, in the same amounts.

The method may further comprise the step of cultivating or growing theplant in the presence of one or more light reflecting and/or refractingmembers, such as silicon-based compounds, such as silicates andsiloxanes. Preferably the silicon-based compound comprises oxides andsilicates in the form of silicate microbeads in sufficiency to coat theground surface, substrate, or the foliage with one or more layers ofbead. As a ground cover, the layer of silicate microbeads may be from0.1 mm to 10 mm deep; and in the case of cultivation of plants insilicates, plants may be sown or rooted in beds or containers filledwith microbeads at an optimal density approximating 2 to 2.5 grams/cc.One or more of the silicon-based compounds preferably comprisessufficient quantities in which to immerse roots of a green plant, forexample, nutrient-moistened hydroponic support media, such as 1 mmdiameter borosilicate microbeads; others preferably compriseSi-chelactants or Si-chelants in an amount between 0.001 ppm to 1 ppm;and yet others preferably comprise siloxanes in an amount between 1 ppmto 0.3%.

In accordance with certain embodiments, one formulation for treatingplants for photosafened enhancement of plant growth comprises one ormore compound selected from the group of glycopyranosides such asindoxyl glycopyranosides, salts and derivatives and combinationsthereof; wherein one or more of said indoxyl glycopyranosides may beselected from the group consisting of indoxyl mannuronide, indoxylmannopyranoside, indoxyl (acyl)_(n) glycopyranoside, and isomers andsalts thereof. The indoxyl (acyl)_(n) glycopyranoside may compriseindoxyl (acetyl)_(n) glycopyranoside wherein n=1-4, such asindoxyl-acetyl-mannopyranoside. The formulation also may comprise one ormore surfactants and/or one or more silicon-based compounds, such as asilicate.

In accordance with certain embodiments, one formulation for treatingplants for photosafened enhancement of plant growth comprises one ormore compound selected from the group of glycopyranosides, such asmannosides including mannose; α-D-mannose; mannose sulfate, mannosephosphate, and salts (e.g., potassium and ammonium salts) thereof;complex glycans with mannose terminal ligand (complex glycans have thehighest potency in the range of 0.1 to 10 ppm) including,α-D-trimannoside, α1-3,α1-6-mannotriose; mannose alcohol, mannitol; andmannuronate; and blends thereof; mannosides systems for treatment ofplants supplemented with 0.5-12 ppm Mn⁺² and 1-50 ppm Ca⁺², preferablychelated, most preferably as diammonium or disodium salts of EDTA, mostpreferably as 1-6 ppm Mn⁺² as disodium-EDTA and 5-20 ppm Ca⁺² asdiammonium-EDTA; mannoside system of pentaacetyl-α-D-mannopyranosepre-solubilized in organic solvents such as methanol followed by aqueousdilution to 1-1000 ppm penta-acetyl-α-D-mannopyranose in a formulationcontaining 0.5-12 ppm Mn⁺² and 1-50 ppm Ca⁺²;penta-acetyl-α-D-mannopyranose in the range of 1 ppm to 1000 ppm,preferably 8 ppm to 80 ppm, pre-dissolved in methanol, and then dilutedinto aqueous solution in the presence of the divalent cations, 0.5-12ppm Mn⁺² and 1-50 ppm Ca⁺²; methyl-α-D-Mannoside (αMeM);ethyl-α-D-Mannoside (αEtM); poly-alkyl-α-D-Mannoside;tetra-alkyl-α-D-Mannoside; tetra-methyl-α-D-Mannoside,tetra-ethyl-α-D-Mannoside; tetra-propyl-α-D-Mannoside;poly-O-acyl-D-Mannopyranose; penta-acyl-α-D-mannopyranose;poly-O-acetyl-D-mannopyranose; penta-acetyl-α-D-mannopyranose,aryl-α-D-Mannoside, indoxyl-α-D-Mannopyranoside, methyl-α-D-Mannoside(αMeM); ethyl-α-D-Mannoside (αEtM); propyl-α-D-Mannoside (αPM); aryl-,alkyl-, and/or aryl-polymannoside; indoxyl-α-D-trimannopyranoside in therange of 3 ppm to 1000 ppm αMeM or αEtM, preferably 20 ppm to 200 ppm;aryl-α-D-Mannosides in the range of 2 ppm to 5000 ppm, most preferably80 ppm to 800 ppm; indoxyl-α-D-Mannoside;tetra-O-acetyl-D-mannopyranose, mixed alpha and beta anomers in therange of 150 ppm to 800 ppm, preferably 300 ppm to 600 ppm; andpenta-acetyl-α-D-mannopyranose in the range of 1 ppm to 1000 ppm;preferred range 8 ppm to 50 ppm, pre-dissolved in methanol, and thendiluted into aqueous solution in the presence of the divalent cations,0.5-12 ppm Mn⁺² and 1-50 ppm Ca⁺².

In accordance with certain embodiments, treating plants withformulations for enhancing plant growth results in the endogenousproduction of one or more corresponding(glycopyranosyl)_(n)-glycopyranosyl-proteins or(glycopyranosyl)_(n)-proteins in an amount between about 0.0001 ppm to20% of proteins; where the glycan n=1-3.

In accordance with certain embodiments, another suitable formulation fortreating plants and/or enhancing growth comprises one or more compoundsselected from a group consisting of cyclic alkyl glycopyranosides; saltsand derivatives of the cyclic alkyl glycosides; cyclic acyl glycosides;salts and derivatives of the cyclic acyl glycopyranosides; andcombinations thereof; such as one or more methyl glycopyranosides; saltsand derivatives of the methyl glycopyranosides and combinations thereof;and, or one or more polyacetylglycopyranoses; salts and derivatives ofthe polyacetylglycopyranoses and combinations thereof; and mostpreferably one or more mixed polyacetylmannopyranoses; salts andderivatives of the mixed polyacetylmannopyranoses and combinationsthereof; and pentaacetylmannopyranose.

In accordance with certain embodiments, silicate microbeads areintroduced as convenient and applicable mechanical supports forhydroponics that can be released from roots to exhibit visuallydiscernible responses. Silicate microbeads refract light, effectivelyredistributing light toward the phylloplane. Microbeads manufacturedfrom silicates have the clean clarity of glass, provide a relativelyconsistent support medium, are autoclavable to sterility, may becleansed and re-used, and may be conveniently released from rootswithout injury to said root system.

In accordance with certain embodiments, a method for treating and forphotosafening plants comprises the step of applying an effective amountof one or more compounds selected from the glycopyranosidic groupconsisting of preferred polyacyl-D-glycopyranoses; salts and derivatives(e.g., acetyl) of said acyl-D-glycopyranoses; and mixtures andcombinations thereof; wherein said effective amount is preferablybetween 1 ppm to 80,000 ppm.

In accordance with certain embodiments, a method for chemical synthesisof one or more compounds selected from a glycopyranosidic groupconsisting of polyacyl-D-glycopyranoses and salts and derivatives (e.g.,acetyl) of said acyl-D-glycopyranose.

In accordance with certain embodiments, a method of treating orphotosafening plants comprises the step of applying an effective amountof one or more of a trimannose (e.g., 0.5 ppm), amethyl-alpha-D-mannoside (e.g., 5 ppm, and/or a mannose pentaacetate,e.g., 50 ppm).

Although the present inventor is not to be bound by any theory, it isbelieved that binding of specific glycopyranosyls and(glycopyranosyl)_(n)-glycopyranosyls to glycoproteins, do so incompetition to the displacement of certain sugars. The displaced sugars,such as glucose, are released from certain intracellular glycoproteinstorage structures, such as lectins, during times of reducedintracellular sugar content. When a plant is under stress, particularlywhen stressed by exposure to light saturation, sugar is depleted.Displacement of glucose from storage is a mechanism for the release ofsugar to partially make up for the loss to stress, thereby effectivelyphotosafening the plant.

The formulations disclosed herein may be applied to all parts of theplant individually or in combination, including the leaf, shoot, root,stem, flower, seed and/or fruit depending on the nature of theformulation utilized and the result desired. The formulations may beapplied to the plants using conventional application techniques such asfoliar spraying, misting, fogging, side dressing, dipping, sprenchinq(spray-drenchinq), foliar wetting, and root drenching; of which shootinput and root uptake are preferred methods. Plants nearing or atmaturity may be treated at any time before and during seed development.Fruit bearing plants may be treated before or after the onset of bud orfruit formation. Fruit bearing plants may be treated both before andafter fruiting, with preference for applications within a 24 to 48 hperiod to which maximum sugar content is desired. Improved growth occursas a result of the exogenous application of one or more glycopyranosidesin response to light saturation, particularly, as may result from lightrefracted by silicate microbeads.

Unless otherwise defined, all technical and scientific terms employedherein have their conventional meaning in the art. As used herein, thefollowing terms have the meanings ascribed to them.

“Enhance(s) growth” or “enhancing growth” refers to promoting,increasing and/or improving the rate of growth of the plant and/orincreasing and/or promoting an increase in the size of the plant.Without wishing to be bound by any particular theory regarding themechanism by which the compositions and methods of the embodimentsdisclosed herein enhance the growth of a plant, it is believed that whenlight reflecting and/or refracting member such as a silicon-basedcompound such as silicate microbeads refract sunlight, the amount oflight incident to foliage is significantly increased over controlswithout light from the light reflecting and/or refracting member,allowing greater efficiency of photosynthesis. However, under saturatedlight conditions, photorespiration and photoinhibition may also increasein some plant varieties and exogenous introduction of glycopyranosidesincreases the capacity of an organism to withstand the artificiallyheightened solar light intensities. In such cases, they permitphotosynthetically efficient growth under redirected light, therebyleading to the enhanced growth of the plant.

“Photosafener” refers to compounds, preferably as nutrients, of theembodiments disclosed herein, that may be applied to protect plantsagainst the negative effects of an environmental or exogenous condition.In the embodiments disclosed herein, photosafening is most preferablyfrom negative effects of light saturation, without excluding othersafener influences. For example, effects such as photoinhibition andphotorespiration may negatively impact growth and reproduction of aplant being cultivated under a light saturated environment; but upontreatment with a photosafener, a decrease or elimination of an expectedconsumption of photosynthate, characterized by midday wilt, may beobserved.

“Plant” refers to any life form that, by means of photosynthesis, sugarproduced. This plant process includes, but is not necessarily limited tothe following: lower life forms including prokaryotes, eukaryotes,bacteria, algae, lichens, cryptophytes, and fungi; and higher life formsincluding, vascular plants, such as angiosperms and gymnosperms and thelike. The methods and formulations of the embodiments disclosed hereinare advantageous for many applications including, but not limited to,hydroponic, agricultural, horticultural, maricultural, aquacultural,water cultural, algal cultural, floricultural and silviculturalapplications. The methods and formulations of the embodiments disclosedherein are advantageous for many outdoor and indoor applicationsincluding, but not limited greenhouse, nursery, landscape, bedding, rowcrop, field, irrigated, non-irrigated, home garden, formal garden,public arena, turf, raceway, vat, batch, continuous, fermenter,cryostat, immobilized, micropropagation, meristem, laboratory, pilot,and mass culture and like plant fields.

“Surfactant” refers to surface-active i.e., agents that modify thenature of surfaces, often by reducing she surface tension of water. Theyact as wetting agents, spreaders, dispersants, emulsifiers orpenetrants. Typical classes include cationic, anionic (e.g.,alkylsulfates), nonionic (e. g., polyethylene oxide) and ampholytic.Soaps, alcohols, block copolymers and polysiloxanes are other examples.

“Silicon-based compound” refers to a compound containing silicon,hereinafter referred to as Si, such as silicates and their salts such asthe sodium, potassium, or ammonium salts and the like. Silicates includeborosilicate, sodalime silicate; and for example, in the form of glass,crystal, marbles, beads, microbeads, microballoons, shot and crushedglass. Silicate microbeads are spherical and sized according to nominalmodal diameters, “nmd” (US Sieve range), often in the micron “μm” range.

“Aqueous”, with reference to solutions or solvents, refers to solutionsor solvent systems that consist primarily of water, normally greaterthan 25% water, and can be essentially pure water in certaincircumstances. For example, an aqueous solution or solvent can bedistilled water, tap water, irrigation water, well water or the like.However, an aqueous solution or solvent can include water, havingsubstances such as pH buffers, pH adjusters, organic and inorganicsalts, alcohols (e. g., methanol, ethanol, and propanol), sugars, aminoacids, or surfactants incorporated therein. The aqueous solution orsolvent may also be a mixture of water and minor amounts of one or moreco-solvents, including agronomically suitable organic co-solvents, whichare miscible therewith, or may form an emulsion therewith. Agronomicallysuitable organic solvents include, for example, acetone, methanol,ethanol, propanol, butanol, limonene, paraffin oils, silanes, esters,ethers, and emulsifiers.

“Glycoprotein” refers to any protein with a bound sugar moiety.Glycoproteins may, thereby, store certain sugars and competitively bindstructurally related substituted sugars. Highly preferred glycoproteinsallow displacement and release of sugars and are exemplifed by lectins.Furthermore, lectins may be referred to as, for example,phytohaemagglutinins, haemagglutinins, and agglutinins; andconcanavalins represent specific examples of glycoproteins found at upto 20% of the protein content of beans. Glycoproteins are made up ofglycopyranosyl-glycoproteins,polysaccharide-glycopyranosyl-glycoproteins andsubstituted-glycopyranosyl-glycoproteins; and sugar moieties may competefor binding sites on the tetramers. A pair of glycoprotein tetramers mayhave multiple glycopyranosyls bound to the complex. The preferredglycoproteins incorporate manganese and calcium into theirglycopyranosyl-binding sites; therefore, soluble manganese and calciumare required in formulations involving glycopyranosides.

“Redistributed light” includes light, preferably as photosyntheticallyactive radiation, that, from a primary source (whether natural orartificial), is refracted or reflected.

“Percent” or “percent” is percent by weight unless otherwise indicated.

“Ppm” refers to parts per million by weight.

“cc” refers to cubic centimeter in volume, equivalent to a milliliter,ml.

“M” refers to molar concentration, “mM” refers to millimolarconcentration, and “μM” refers to micromolar concentration.

Suitable glycopyranosides which may be active using the formulations ofthe embodiments disclosed herein include, but are not necessarilylimited to: aminophenyl-α-D-mannopyranoside;tetra-acetyl-D-mannopyranose; tetra-methyl-α-D-mannopyranoside;phenyl-α-D-mannopyranoside; benzyl-α-D-mannopyranoside;4-aminophenyl-indoxyl-α-D-mannopyranoside; dimethyl-α-D-mannopyranoside;diacetyl-D-mannopyranose; trimethyl-α-D-mannopyranoside;triacetyl-D-mannopyranose; penta-methyl-α-D-mannopyranoside;penta-acetyl-α-D-mannopyranose; methyl-α-D-mannopyranoside;acetyl-D-mannopyranose; 2,3,4,6-tetra-O-benzyl-α-D-glycopyranoside;2,3,4,6-tetra-O-benzyl-α-D-mannopyranoside;para-aminobenzyl-α-D-mannopyranoside;para-nitrobenzyl-α-D-mannopyranoside;para-acetamidobenzyl-α-D-mannopyranoside;1,4-bis(α-D-mannopyranosyloxymethyl)benzene;para-methoxycarbonylbenzyl-α-D-mannopyranoside; benzylidene-D-mannose;(benzylidene)methyl-α-D-mannopyranoside;N⁶-benzyladenosyl-α-D-mannopyranoside; kinetin-α-D-mannopyranoside;indoxyl-α-D-glucopyranoside; indoxyl-α-D-mannopyranoside;indole-acetic-α-D-mannopyranoside; naphthyl-α-D-mannopyranoside;salicin; esculin; 4-methylumbelliferyl-glycopyranoside;4-methylumbelliferyl-α-D-mannopyranoside; aromatic bis mannopyranosides;benzyl-3,6-di-O-(α-D-mannopyranosyl)-α-D-mannopyranoside;2-(hydroxymethyl)phenyl-α-D-mannopyranoside; and α-D-glycosidesincluding, but not limited to: indoxyl glycopyranoside; indoxylmannapyranoside; indoxyl galactopyranoside; indoxyl glucapyranoside;indoxyl erythropyranoside; indoxyl threopyranoside; indoxylribopyranoside; indoxyl arabinoside; indoxyl xyloside; indoxyl lyxoside;indoxyl alloside; indoxyl altroside; indoxyl gulaside; indoxyl idoside;indoxyl taloside; indoxyl erythruloside; indoxyl ribuloside; indoxylxyluloside; indoxyl psicoside; indoxyl fructoside; indoxyl sorboside;indoxyl tagatoside; indolyl, (acetyl)_(n) glycoside, where n=1-4;indolyl (acetyl)n glucoside; indonlyl (acetyl)_(n) galactoside; indolyl(acetyl)n erythroside; indolyl (acetyl)_(n) threoside; indolyl(acetyl)_(n) riboside; indolyl (acetyl)_(n) arabinoside; indolyl(acetyl)_(n) xyloside; indolyl (acetyl)_(n) lyxoside; indolyl(acetyl)_(n) alloside; indolyl (acetyl)_(n) altroside; indolyl(acetyl)_(n) mannoside; indolyl (acetyl)_(n) guloside; indolyl(acetyl)_(n) idoside; indolyl (acetyl)_(n) taloside; indolyl(acetyl)_(n) erythruloside; indolyl (acetyl)_(n) ribuloside; indolyl(acetyl)_(n) xyluloside; indolyl (acetyl)_(n) psicoside; indolyl(acetyl)_(n) fructoside; indolyl (acetyl)_(n) sorboside; indolyl(acetyl)_(n) tagatoside; and aryl groups conjugated with aldoses, suchas, glyceraldehydes; aryl-, acyl-, or alkyl-conjugated with: erythrose,threose, ribose, arabinose, xylose, lyxose, allose, altrose, glucose,mannose, gulose, idose, galactose, talose; and D-arabino-hexopyranoside;and with ketoses, such as dihydroxyacetone, erythrulose, ribulose,xylulose, psicose, fructose, sorbose, tagatose, furanose, pyranose,glucopyranose, fructofuranose, β-D-fructofuranoside, fructopyranose,xylopyranose and their derivatives, e.g., glycuronides, glycosamines;and with 2-acetamido-2-deoxy-α-D-glycopyranose; sophorose;2-O-α-D-mannopyranosyl-D-mannose; α-D-mannose-sulfate;α-D-mannose-phosphate; α-D-hexose-sulfate; and α-D-hexose-phosphate; andglycopyranosylglycopyranosides, such as, disaccharide, oligosaccharide,polysaccharide, fructofuranose, β-D-fructofuranoside,D-arabino-hexopyranoside, 2-O-β-D-mannopyranosyl-D-mannose, sophorose,sucrose, and maltose; and other substituted hexoses, such as,2-acetamido-2-deoxy-α-D-glycopyranose, α-D-mannose-sulfate;α-D-mannose-phosphate; α-D-hexose-sulfate; and α-D-hexose-phosphate; andany conjugated electron donating aryl-isomer, metabolite, salt, hydrate,ester, amine, surfactant-linked derivative and other suitablebiologically or chemically equivalent derivative and combination,thereof, and derivatives, thereof.

In the foregoing, the value of n is from 1 to 4.

Suitable glycoproteins which may result endogenously from externalapplication of glycopyranosides using the formulations of theembodiments disclosed herein include, but are not necessarily limited tothe following glycosides as glycopyranosyls as bound to appropriateglycoproteins: aminophenyl-α-D-mannopyranoside;tetra-acetyl-D-mannopyranose; tetra-methyl-α-D-mannopyranoside;phenyl-α-D-mannopyranoside; benzyl-α-D-mannopyranoside;4-aminophenyl-indoxyl-α-D-mannopyranoside; dimethyl-α-D-mannopyranoside;diacetyl-D-mannopyranose; trimethyl-α-D-mannopyranoside;triacetyl-D-mannopyranose; penta-methyl-α-D-mannopyranoside;penta-acetyl-α-D-mannopyranose; methyl-α-D-mannopyranoside;acetyl-D-mannopyranose; 2,3,4,6-tetra-O-benzyl-α-D-glycopyranoside;2,3,4,6-tetra-O-benzyl-α-D-mannopyranoside;para-aminobenzyl-α-D-mannopyranoside;para-nitrobenzyl-α-D-mannopyranoside;para-acetamidobenzyl-α-D-mannopyranoside;1,4-bis(α-D-mannopyranosyloxymethyl)benzene;para-methoxycarbonylbenzyl-α-D-mannopyranoside; benzylidene-D-mannose;(benzylidene)methyl-α-D-mannopyranoside;N⁶-benzyladenosyl-α-D-mannopyranoside; kinetin-α-D-mannopyranoside;indoxyl-α-D-glucopyranoside; indoxyl-α-D-mannopyranoside;indole-acetic-α-D-mannopyranoside; naphthyl-α-D-mannopyranoside;salicin; esculin; 4-methylumbelliferyl-glycopyranoside;4-methylumbelliferyl-α-D-mannopyranoside; aromatic bis mannopyranosides;benzyl-3,6-di-O-(α-D-mannopyranosyl)-α-D-mannopyranoside;2-(hydroxymethyl)phenyl-α-D-mannopyranoside; and α-D-glycosidesincluding, but not limited to: indoxyl glycopyranoside; indozylmannopyranoside; indoxyl galactopyranoside; indoxyl glucopyranoside;indoxyl erythropyranoside; indoxyl threopyranoside; indoxylripyranoside; indoxyl arabinoside; indoxyl xyloside; indoxyl lyxoside;indoxyl alloside; indoxyl altroside; indoxyl guloside; indoxyl idoside;indoxyl taloside; indoxyl erythruloside; indoxyl ribuloside; indoxylxyluloside; indoxyl psicoside; indoxyl fructoside; indoxyl sorboside;indoxyl tagatoside; indolyl (acetyl)_(n) glycoside, where n=1-4; indolyl(acetyl)n glucoside; indoyl (acetyl)_(n) galactoside; indolyl (acetyl)nerythroside; indolyl (acetyl)_(n) threoside; indolyl (acetyl)_(n)riboside; indolyl (acetyl)_(n) arabinoside; indolyl (acetyl))_(n)xyloside; indolyl (acetyl)_(n) lyxoside; indolyl (acetyl)_(n) alloside;indolyl (acetyl)_(n) altroside; indolyl (acetyl)_(n) mannoside; indolyl(acetyl)_(n) guloside; indolyl (acetyl)_(n) idoside; indolyl(acetyl)_(n) taloside; indolyl (acetyl)_(n) erythruloside; indolyl(acetyl)_(n) ribuloside; indolyl(acetyl)_(n) xyluloside; indolyl(acetyl)_(n) psicoside; indolyl (acetyl)_(n) fructoside; indolyl(acetyl)_(n) sorboside; indolyl (acetyl)_(n) tagatoside; and aryl groupsconjugated with aldoses, such as, glyceraidehydes; aryl-, acyl-, oralkyl-conjugated with: erythrose, threose, ribose, arabinose, xylose,lxose, allose, altrose, glucose, mannose gulose, idose, galactose, andtalose; and with ketoses, such as dihydroxyacetone, erythrulose,ribulose, xylulose, psicose, fructose, sorbose, tagatose, furanose,pyranose, glucopyranose, fructopyranose, xylopyranose and theirderivatives, e.g., glycuronides, glycosamines; and with2-acetamido-2-deoxy-α-D-glycopyranose; α-D-mannose-sulfate;α-D-mannose-phosphate; α-D-hexose-sulfate; and α-D-hexose-phosphate; andwith glycopyranosylglycopyranosides, such as, D-arabino-hexopyranoside;fructofuranose, β-D-fructofuranoside, sophorose, sucrose, maltose, and2-O-α-D-mannopyranosyl-D-mannose, disaccharide,(glycopyranosyl)_(n)-glycopyranosyl oligosaccharide, and polysaccharide;and any conjugated electron donating aryl-isomer, metabolite, salt,hydrate, ester, amine, surfactant-linked derivative and other suitablebiologically or chemically equivalent derivative and combination,thereof, and derivatives, thereof. In the foregoing, the value of n isfrom 1 to 4.

The light reflecting and/or refracting member of the embodimentsdisclosed herein includes silicon-based components that preferablycomprise one or more of the following: silicates, glass, or chelatedsilicon salts in forms which include, but are not necessarily limited tothe following: borosilicate, sodalime, leaded glass, quartz glass,quartz, glass shot, glass microbeads, plastic microbeads, metallicmicrobeads, micromirrors, microballoons. The light reflecting and/orrefracting member may be in various forms, including but not limited tobeads, rods, shards, particles, crushed glass, sheets, etc.

Silicate microbeads are polished spheres of small diameter, commerciallyavailable in sizes ranging from 45 μm to 10 millimeters (mm) in diameterand may be obtained from sodalime or borosilicate as commerciallymanufactured. Microbeads resemble microscopic marbles. Sieved microbeadsare available in bulk, are high in silica content, and are resistant towetting, weathering and corrosion.

The formulations disclosed herein may be applied to virtually anyspecies of living organism that synthesize sugar. Such organisms, asnoted above, include innumerable agricultural and decorative plants thatmay be the source of food, fuel, fiber, florals, pharmaceuticals,nutriceuticals, botanicals, seeds, and structural materials. Servicesprovided by plants that be enhanced include bioremediation, carbonsequestration, natural products synthesis, and aesthetics. Further,plants and their varieties, patented or not, which may benefit from themethods and formulations include, but are not limited to those that havebeen genetically modified includng hybridized, chimeric, transgenic,cross-bred, mutated, and plants which include recombinant DNA or RNA orhave had their DNA or RNA otherwise modified or introduced. These listsare intended to be exemplary and are not intended to be exclusive. Otherplants which may benefit by application of the compositions and methodsdisclosed herein can be readily determined by those skilled in the art.

The methods and compositions disclosed herein may be used to enhancegrowth in juvenile and mature plants, as well as cuttings, stolons,bulbs, rhizomes, colonies, unicellular suspensions, micropropagativetissue, meristems, calli, protocorms, roots, shoots, flowers, stems andseeds. Generally, however it s desirable that, for vascular plantapplications, the plants include at least the sprouted cotyledon, i.e.,“seed leaves.” Sprouted cotyledons are also preferred for rootapplications because their development is, some extent, indicative ofglycoprotein content that may reach as high as 25% cotyledon weight. Ingeneral, roots and shoots may be treated because many sugars aretransported throughout shoots from roots.

The embodiments disclosed herein provide methods for treating plants,for increasing the amount of one or more glycopyranosides fordisplacement of glucose from storage in a plant, for enhancing thegrowth of the plant, and for chemical manufacturing of certain of theaforesaid glycopyranosides. These methods typically involve theapplication of reaquired elemental components, calcium and manganese;the application of a preferred α-D-glycopyranoside component; and this,in conjunction with saturated light afforded by refraction or reflectionfrom exposure the plant to a light reflecting and/or refracting member,such as silicon-based component. In the event that anaryl-α-D-glycopyranoside is available, these methods preferably involvethe application of the electron-donating-α-D-glycopyranoside.

A. Aryl -α-D-glycopyranoside

Aryl-α-D-glycopyranosides, such as benzyl adenine-α-D-glycopyranosides,are compounds that generally may be applied to plants. According to themethods, compositions and systems of the emboddments disclosed herein,crop yields may be enhanced effectively and consistently by providingthem in conjunction with light saturation, preferably in the presence ofa light reflecting and/or refracting member, such as a silicon-basedcomponent. For high potency response, aryl-α-D-glycopyranosides may beapplied to the plant in conjunction with light saturation, as forexample by light refraction from silicon-based components in accordancewith the methods and compositions disclosed herein. In this preferredinstance, indoxyl glycopyranosides utilized in the methods andformulations are commercially available and may also be synthesizedaccording to known methods.

Any number of indole-glycosidic compounds, such as the highly preferredindoxyl mannopyranoside, may be used in the methods and formulationsdisclosed herein, including, but not limited to, those specificallylisted above, as well as, metabolites, and all salts, hydrates, esters,amines, surfactant-linked derivatives, and other-biologically orchemically equivalent derivatives and combinations thereof. Generally,the ratio of dry weight applied to dry weight plant is approximately1:1000 to 1:10⁹.

B. Silicon-Based Components

The silicon-based component of the embodiments disclosed hereincomprises any silicate compound. The silicon-based component ispreferably used in conjunction with formulations of glycopyranosides.Specific examples of silicon-based components include, but are notlimited to, silicates, borosilicate and sodalime silicate; silicates inthe form of glass include crushed glass, quartz glass, borosilicate,sodalime glass, leaded glass; and chemically equivalent derivativesthereof and combinations thereof. Silicates come in various formsincluding glass, quartz, sand, earth, and soil; and silicate microbeadsare available in the form of shot, microspheres, marbles, discs,microballoons, sand, and crushed glass. Microbeads may be dyed, colored,and coated; may be attached to surfaces with adhesives, paints, gluesand pastes; and microbeads may be unattached or incorporated into oronto the substrate. Microbeads may be coated with dyes, resins,pigments, paints, microbials, probiotics, genetic components, bacteria,yeasts, elements, compounds, organic compounds, inorganic compounds,salts, nutrients, pesticides, UV-blockers, and anti-reflectivecompounds.

C. Application

The α-D-glycopyranosidic component may be applied in conjunction withlight saturation resulting from the presence of the light reflectingand/or refracting member such as a silicon-based component, or they maybe separately or co-applied to achieve beneficial results in the methodsfor treating plants. In order to insure the optimal growth of a plantunder environmental conditions of light saturation in the presence ofthe light reflecting and/or refracting member such as silicatemicrobeads, separate or co-application of photosafeners before or at theonset of light saturation will insure uninterrupted productivity.

The methods of the embodiments disclosed herein may include theapplications of the glycopyranosyl components and distribution of thelight reflecting and/or refracting member from separate sources; or theseparate application, wherein, the plant is immersed in the lightreflecting and/or refracting member adjusted from pH 6 to neutral,first, followed by the application of the α-D-glycopyranosides; and viceversa. The components may be applied separately, or formulated togetherand then applied, to the roots and/or the shoots in any combination orsequence such as those described above. The reverse orders may beapplicable.

Although the components may be applied in a solid form, it is oftenadvantageous to provide the formulation in liquid form or liquidsuspension, such as by solubilizing a component in an aqueous oragronomically suitable organic solvent or carrier to produce aqueous ororganic solutions for application to the plant. The amount ofα-D-glycopyranoside which is solubilized in the carrier will depend uponthe particular compounds selected and the method of application. Forexample, aryl-α-D-glycopyranoside may be solubilized in the carrier byadding the aryl-α-D-glycopyranoside to the carrier and allowing it todissolve. In some instances, the application of stirring, agitation, oreven heat may facilitate dissolution in a carrier blend such as acetone.Typically, the aryl-α-D-glycopyranoside is applied as an aqueoussolution having an aryl-α-D-glycopyranoside concentration in the rangebetween 0.1 ppm and 10,000 ppm by weight of the composition inclusive,preferably between 1 ppm and 1000 ppm, inclusive, for application toopen field crops at a rate of 1 to 100 gallons per acre, preferably 3 to300 gallons per acre.

Typically, the application of α-D-glycopyranosides in conjunction withthe light reflecting and/or refracting member such as light refractedfrom silicon-based components is undertaken achieve beneficial resultsin the methods for treating plants. For example, α-D-glycopyranosidesmay be formulated with plants that were previously immersed in a lightreflecting and/or refracting member with, for example, 600 μm to 1 mmnmd silicate microbeads filling a container for rooting a plant, such ascorn. As a further example, 210 grams of 700 μm road microbeads, fill a100 cc pot. Approximately three to twelve weeks after sowing the corn inbuffer-moistened microbeads, 0.1 to 3 mM α-D-glycopyranosides areapplied to the sprouted corn plant.

While the compositions of the embodiments disclosed herein may consistessentially of the aqueous solutions of the α-D-glycopyranoside, thereare times at which oil soluble compounds may be formulated inagronomically suitable organic solvents. For example, highlysubstituted, non-polar aryl-α-D-glycopyranosides may be formulated asacetone concentrates with paraffin oil as the spreader for applicationin appropriate crop emulsions, hydrosols or organic films.

The compositions of the embodiments disclosed herein may also includeany of a wide variety of agronomically suitable additives, adjuvants, orother ingredients and components that improve, or at least do nothinder, the beneficial effects of the compositions disclosed herein(hereinafter “additives”). Generally accepted additives for agriculturalapplication are periodically listed by the United States EnvironmentalProtection Agency. For example, foliar compositions may contain asurfactant and a spreader present in an amount sufficient to promotewetting, emulsification, even distribution and penetration of the activesubstances. Spreaders are typically orqanic-alkanes, alkenes orpolydimethylsiloxanes which provide a sheeting action of the treatmentacross the leaf. Suitable spreaders include paraffin oils andpolyalkyleneoxide polydimethylsiloxanes. Suitable surfactants includeanionic, cationic, nonionic, and zwitterionic detergents, amineethoxylates, alkyl phenol ethoxylates, phosphate esters, PEG,polymerics, polyoxyethylene fatty acid esters, polyoxyethylene fattydiglycerides, sorbitan fatty acid esters, alcohol ethoxylates, sorbitanfatty acid ester ethoxylates, ethoxylated alkylamines, quaternaryamines, sorbitan ethoxylate esters, alkyl polysaccharides, blockcopolymers, random copolymers, trisiloxanes, chelactants, and blends.Surfactant preference is for polyalkylene oxides, polyalkylene glycols,and alkoxylate-fatty acids. Blends are highly effective such as anorganosiloxane nonionic surfactant Dow Corning+Pluronic blend, which useis demonstrated in our examples. Preferred commercial aqueoussurfactants include TEEPOL; TWEEN; TRITON; LATRON; PLURONIC; TETRONIC;SURFONIC; SYNPERONIC; ADMOX; DAWN, and the like. Commercial emulsifiersfor combination with organic solvent formulations include RHODASURF,TERGITOL and TWEEN. Commercial spreaders include paraffin oil. Siloxanesinclude TEGOPREN, PELRON, AGRIMAX, DOW CORNING, X-77, SILWET and thelike. Penetrants such as sodium dodecylsulfate, formamides and loweraliphatic alcohols, may be used. Alkoxylation of an active component orotherwise chemically modifying the active components by incorporation apenetrant substance is useful because formulation without additionalsurfactant is achieved.

Large molecules, such as maltose and other pyranose components, poseproblems related to cellular penetration. Addition of diatomaceousearth, carborundum, fine bentonite, clay, fine sand or alumina may beadded to the compositions of the embodiments disclosed herein to scratchthe leaf surface and assist with penetration. Small quantities (e.g.,0.03-0.3 percent) of sterile diatomaceous earth are preferred additionsto the adjuvant formulation to enhance penetration. In some cases, suchas cabbage, in which cells are tough, gentle movement of the diatomsacross the leaf surface by mechanical rubbing or pressurized treatmentsmay be employed. Penetration may not be the only barrier to activitybecause maltose shows lower potency than alpha-MeG, but 9× higherpotency than beta-MeG.

In addition to the foregoing additives, the compositions of theembodiments disclosed herein also advantageously may include one or morefertilizers. Suitable fertilizers for inclusion in the compositions,methods and systems of the embodiments disclosed herein will be readilydeterminable by those skilled in the art and include conventionalfertilizers containing elements such as nitrogen, phosphorus, potassium,sulfur, magnesium, calcium, iron, zinc, manganese, boron, copper,molybdenum, cobalt, nickel, silicon, carbon, hydrogen, oxygen and thelike.

In accordance with certain embodiments, on suitable formulationcomprises the following minimal essential nutrients:

Final concentration of nutrients in the buffered culture medium is asfollows:

Micronutrients Fe 1 ppm Mn 1 ppm Si 1 ppm Zn 0.6 ppm B 0.2 ppm Cu 0.3ppm Co 0.0001 ppm Mo 0.0003 ppm Ni 0.001 ppb Secondary nutrients Ca 5ppm S 2 ppm Mg 2 ppm Major nutrients N 50-250 ppm P 10-30 ppm K 10-50ppm

Nitrogenous fertilizers (i.e., plant nutrients containing nitrogen) arecurrently preferred, particularly, nitrogenous fertilizers containingammoniacal nitrogen (that is, nitrogen in the form of ammonium ion).Nitrate fertilizers may be included in the methods disclosed herein. Inparticular, in cases requiring foliar uptake, nitrate and low biureturea fertilizers may be utilized. Fertilizers may be fed to plantsbefore, during or after treatment through the root or the shoot. Theamount of fertilizer added to the compositions of the embodimentsdisclosed herein will depend upon the plants to be treated, and thenutrient content of the culture medium. Typically, the conventionalfertilizer is included in an amount of between 0.1 percent, and 2percent, preferably between 0.2 percent, and 1 percent, and morepreferably between 0.4 percent and 0.8 percent by weight of thecomposition.

As noted, the compositions of the embodiments disclosed herein may beapplied to the plants using conventional application techniques. Plantsnearing or at maturity may be treated at any time before and during seeddevelopment. Fruit bearing plants may be treated before and after theonset of bud or fruit formation. Of particular note is novelexploitation of the alkaline qualities of sodalime silicate microbeadsto improve distribution and sequestration of carbon dioxide by thehydroponic support medium. The culture of plants in silicate microbeadswas achieved by development of a system for maintaining pH-appropriateenvironments with continuous flow through of acidic plant nutrients,such as application of elevated levels of carbon dioxide gas duringdaylight periods to aqueous culture media or by direct injection intosodalime silicate microbeads.

The compositions may be applied to the plant at a location includingleaves, fruit, flowers, shoots, root, seed, and stem. The compositionsmay be applied to the leaves, seed or stem by spraying the leaves orcoating the seeds with the composition. The composition may be appliedto the shoot or root by spraying the shoot or root, or dusting the shootor root, or side-dressing the root with slow-release encapsulations orformulations, or dipping the shoot or root in a bath of the composition,or drenching the soil in which the plant is being cultivated with thecomposition, or spray-drenching the leaves and stem of the plant suchthat the soil in which the plant is being cultivated becomes saturatedwith the composition.

Foliar application (that is, application of the composition to one ormore leaves of the plant) of the α-D-glycopyranosides compositions ofthe embodiments disclosed herein is currently preferred. The compositionwill normally be applied to the leaves of the plant using a spray.However, other means of foliar application, such as dipping, brushing,wicking, misting, electrostatic dispersion and the like of liquids,foams, gels and other formulations may also be employed.

Foliar sprays can be applied to the leaves of the plant usingcommercially available spray systems, such as those intended for theapplication of foliar fertilizers, pesticides, and the like, andavailable from commercial vendors such as FMC Corporation, John Deere,Valmont and Spraying Systems (TEEJET). If desired, photosafeners may beapplied to plants in rapid sequence from separate nozzles in separatereservoirs. Chemically compatible combined mixtures may be preferred formany applications to produce improved plant growth. High foliar contentof photosafeners with foliar calcium and manganese maintain high ratesof growth in light saturated environs, with greatest response whenplants are exposed to water, nutrients, warmth and high light intensityconsistent with good agricultural practices. Side-dressing is alsoapplicable. High potency is achieved by foliar application ofcompositions containing one or more select compounds in combination with1 to 24 ppm Mn and 1 to 250 ppm Ca or readily metabolized salts, organiccompounds, or chelates, thereto.

In the embodiment wherein the whole plant, root or shoot is dipped in abath of the formulation, it is preferred to pulse the application of theformulation by dipping the plant in the bath containing the formulationfor a period of time and then removing it from the formulation. Thedipping period may be from 0.1 h to 72 h, and is preferably from 0.5 to8 h.

The formulations of the embodiments disclosed herein also may be appliedto plant tissues, such as cell suspensions, callus tissue cultures, andmicropropagation cultures. Such plant tissues may be treated with theformulations by adding the formulation to the culture medium in whichthe plant tissues are being cultivated. For example, 10 ppm-50 ppmindolyl acetylmannopyranoside may be added a microbead supportedprotocorm nutrient medium.

Formulations may be formulated at very low concentrations withoutsurfactant or spreader for treatments of roots and liquid suspensionculture media.

In the methods of the embodiments disclosed herein, thearyl-α-D-glycopyranoside formulations are typically applied in theamount of between 3 gallons per acre and 100 gallons per acre, dependingupon the application method. For horticulture applications, theformulations are preferably applied in the amount of between 75 gallonsper acre and 100 gallons per acre. As a standard for consistentcomparisons, treatments of the embodiments disclosed herein arecalibrated to conventional foliar spray ground rig volumes of 20 gallonsper acre. For aerial applications by helicopter or airplane cropdusters, the formulations are preferably applied in the amount ofbetween about 1 gallon per acre and about 10 gallons per acre. Theformulations may be applied in a single application, or in multipleapplications interrupted by periods of photosynthetic activity.Ornamentals and other tender nursery plants meant for indoorhorticulture will frequently require lower concentrations and morefrequent application than outdoor agricultural crops. In generalagricultural practice, withholding pesticidal application to the targetcrop for 2 days prior to and following treatment is recommended toprevent interference. Suitable light and temperature conditions may beachieved by treating plants at any time of day or night. Optimal to hottemperatures, usually above 15° C. to 35° C., may be required aftertreatment. The plants should remain exposed the sunlight or highintensity illumination for a period of time sufficient to allow forincorporation of treatments. Usually, the plants should remain exposedto sunlight or other illumination during daylight photoperiods for atleast eight hours after treatments. Sufficient nutrients should bepresent to support healthy growth. Throughout the growing season aftertreatments, either sun or artificial illumination should have anintensity and duration sufficient for prolonged high rates ofphotosynthesis.

A suitable illumination intensity may be as minimally low as 100 umolphotosynthetically active quanta, with direct sunlight normallyproviding much higher illumination. Prior to treatment, leaf temperatureshould be sufficiently high for optimal growth or hotter, usually above15° C. and up to 38° C. and higher in arid zones. After treatment, theleaf temperature will normally drop as a consequence of improvedtranspiration. It is preferable that the plant be exposed to at least aweek of intense PAR illumination preferably direct sunlight followingapplication of the formulations. Formulations according to theembodiments disclosed herein may be tailored for specific uses,including enhanced yield; early yield; rapid cycling through growingseasons; aftermarket; rooting; branching; flower retention; fruitoptimization; using one or more conjugated compounds which havecommercial impact and with which optimal growth and quality control isbeneficial. In addition to the methods and formulations describedhereinabove, the embodiments disclosed herein also include a plantgrowth enhancing system. The system includes (a) an aqueous immersioncontaining an amount of a silicon-based component which provides supportnecessary for transport from root to shoots in a plant, and (b) anaqueous solution containing an amount of a glycopyranoside, such as thepreferred electron donating aryl-α-D-glycopyranoside, with soluble Caand Mn effective to enhance the growth of the plant.

An example of field crop utilization is to incorporate glass microbeadsinto the long rows of plastic sheets placed under strawberrycultivation. Microbeads may be applied over an adhesive to coat theplastic or incorporated into the sheets during manufacture. Distributionof a thin layer beneath and on plants will shine light up to foliage.Also, incorporation of microbeads into substrates of, for example,greenhouse walls and support surfaces will become light sources.

Light reflective and/or refractive material such as silicate beads maybe applied to various substrates, such as by adhering, embedding,attaching, molding, integrating, etc. to the substrate, to refractand/or reflect light for the benefit of plant cultivation. Generally,microbeads, crushed glass, glass shards, prisms, quartz sand, and otherreflective materials may be incorporated onto or into surfaces withspecifications that include the following: nominal modal diameters (nmd,US Sieve range) 100 μm (100-170 sieve), 200 μm (60-120 sieve), 300 μm(50-70 sieve), 500 μm (30-40 sieve), and 700 μm (20-30 sieve); hardness500 kg/mm²; density 2.5 g/cc; pH 9; borosilicate and/or sodalimesilicate. For example, glass microbeads may be structurally incorporatedinto or onto a substrate by during baking or in the process of filmmelts to reflectorize a surface. For example, beads may be embedded intothe enamel bake. Alternatively, a layer of microbeads one diameter thickmay be permanently embedded at 40-50% depth to 0.91-0.94 g/cm³polypropylene plastic film or plastic rigid structure after the finalstages of a ˜1150° C. melt process and/or within the glass cooling rangeof approximately ˜500°-750° C.

A commercially feasible method of attachment of microbeads to existinginfrastructures for plant cultivation (such as greenhouses) includesadhesion with a clear bead binder that adheres to glass of themicrobeads and the suitable building surface. The first step includesthe application of one coat of glass-binding adhesive such as epoxy,cyanoacrylate, silicone, paint, polyurethane, hot melt, thermoform,laminate, UV light cure, and the like. The binder may be applied to itsdry-film-thickness a third to half the height of the bead. Applicationof the binder can be achieved by any standard method: spray,electrostatic coating, silkscreen, knife-over-roll, roller coater,sputter coating, or brush. Specifically, in the case of coating clearplastic sheets, the second step in this process may include anapplication of beads; however, for colored surfaces, the second step maybe to apply flotation-treated beads over the wet binder such that thebead sits 25% bead diameter atop a the binder. Flotation prevents beadsfrom sinking to the bottom and will prevent the bead from reflecting thebackground color.

FIG. 14 shows proper microbead embedment in the binder on a plasticsubstrate that results in refraction to foliage and bead retention. Thecircle represents a 700 μm microbead, the dashes are the binder at 40%depth of the microbead, the diagonal lines represent the substrate.Substrates include but are not limited to planting containers orhousings such as pots, trays (including multiwell trays), urns, bowls,cans, barrels, etc., made of wood, plastic, clay, ceramic, metal,concrete, fiberglass, PVC, peat, etc.

The following examples are provided to further illustrate theembodiments disclosed herein, and should not be construed as limitingthereof. In these examples, glycopyranosides, chelates, siloxanes,surfactants, purified water, alcohols, plant nutrients, buffers andtrace minerals were formulated in aqueous solutions for field use. Inthese examples, “1” means liter; “ml” means milliliter; “μm” meansmicron; “cm” means centimeter; “cm²” means cm squared; “cc” means cm“μg” means micrograms; “gm” means grams; “Kg” means kilograms; “mM”means millimolar; “ppm” means parts per million based on weight; and“percent” or “%” means percent by weight of the composition.

Following are examples of specific formulations according to certainembodiments, which advantageously may be employed to treat plants and toenhance growth in plants to increase displacement of glucose fromstorage in plants. The following exemplary formulations are intended toprovide further guidance to those skilled in the art, and do notrepresent an exhaustive listing of formulations.

First Exemplary Formulation: Root Composition Microbeads

Ten rooted plants are each transferred into 4.5 Kg 800 μm nmdmicrobeads, moistened by application with buffered solution (Table 1).It is recommended that the depth of beads be 2 to 10 cm greater than thelength of the roots. In most cases, beds may be 10 cm to 100 cm deep,and preferably 15 cm to 30 cm depth. Where such bedding depth isimpractical, a minimal layer of beads of 1 mm to 10 mm distributed as arefractive coating over the surface of the alternative rooting substratemay be a minimal application.

Indoxyl-α-D-mannopyranoside, dissolved in aqueous solution Preferredconcentration 0.1 to 2 g/L Broad Range Concentration 0.01 to 10 g/L.Volume application: 0.1 ml per plant applied to roots in moistmicrobeads 6 ppm Mn as EDTA 6 ppm Ca as EDTA

Second Exemplary Composition: Foliar Composition Concentration

Approximately 200 grams of beads/cell filled individual 100 cc cells ofplastic flats. Roots of radish are cultivated hydroponically byimmersion of roots in 700 μm nmd shot, pre-moistened with bufferednutrient solution that included soluble Mn and Ca, and plants wereallowed to grow for 72 h prior to treatment withaminophenyl-α-D-mannopyranoside.

Aminophenyl-α-D-mannopyranoside

4-aminophenyl-α-D-mannopyranoside was dissolved in water (APM needsfirst to be solubilized in a small volume (1 ml) of ethanol prior tobeing added into water) with 3 ppm Mn as EDTA, 6 ppm Ca as EDTA, 10%isopropyl alcohol and 1.5 g/L Pluronic L-62. A solution of theformulation was applied to radish foliage. When compared to an identicalcontrol formulation without the aminophenyl-α-D-mannopyranoside, theabove formulation provided a 20% root increase. Foraminophenyl-α-D-mannopyranoside, the proper dose for radish is between 1to 100 μg per plant and preferably between 5 to 50 μg per plant. This isthe equivalent to an application of 75 to 100 gallons per acre at apreferred volume of 100 gallons per acre of up to 2 gm/liter.

EXAMPLE 1

Potters Ballotini sodalime silicate beads were obtained with thefollowing specifications: nominal modal diameters (nmd, US Sieve range)100 μm (100-170 sieve), 200 μm (60-120 sieve), 300 μm (50-70 sieve), 500μm (30-40 sieve), and 700 μm (20-30 sieve); hardness 500 kg/mm²; density2.5 g/cc; pH 9; and sodalime silicate. A 1 cm layer of Perlite® wasinserted into each well to hold microbeads in container. The wells ofplastic Seed Starter™ trays (Jiffy®, Ferry-Morse Seed Company®, Fulton,Ky. 42041 USA) were filled with microbeads. Large 700 μm silicate beadswere utilized to fill perforated containers. A wash of a quarter volumeof buffered solution of 1 mM monopotassium phosphate and 3 mMmonoammonium phosphate over microbeads was dispensed over trays andallowed to drain. The buffered wash was not rinsed out and providedmajor nutrients while maintaining the microbeads between pH 6 toneutral. Daily or continuous irrigation with essential nutrients loadedin 2 mM to 3 mM phosphates buffer, pH 6, maintained a mildly acidenvironment. Therefrom, water-culture nutrient media was developed thatincorporated the phosphates buffer. Immediately before sowing seeds,microbeads were saturated with a buffer-modified nutrient solution inwhich nutrient phosphates (1 mM K₂HPO₄ and 1.3 mM KH₂PO₄; approximatelypH 6) were utilized both as nutrient and buffering sources. Furthermore,to insure availability of nutrients, Mg, and trace metals were chelated,from Sequestar® Multi-Nutrient Chelate, Monterey Chemical Company, P.O.Box 35000, Fresno, Calif. 93745 USA; and Ca as disodium EDTA. Thebuffered chelant nutrient solution for neutralizing alkaline sodalimesilicate microbeads is hereafter referred to as the “nutribead”solution, given in Table 2. With good drainage, a low flow dripfertigation (<1 L/h) from above was provided by wicking, meteredinjection pumps, or hourly misting, to insure pH-stability, availabilityof nutrients and aeration.

Individual plants were started from seeds, bulbs, or vegetative clones,inserted into containers of pre-moistened microbeads. Seedlings includedryegrass and corn; bulbs were of crocus and paperwhite narcissus; andvegetative cuttings were from coleus. Seeds generally germinated andwere selected according to day of emergence of first roots as controland treatment sets. Roots were treated thereafter.

Plants were cultivated under controlled environmental conditions asfollow: GE Ecolux® plant and aquarium F40T12 fluorescent illumination,photosynthetically active radiation (PAR) of 100 μEin·m³¹ ²·s⁻¹, dielcycle of 16:8 h light:dark, 28:26° C., 10% to 20% relative humidity.Indoxyl glycopyranoside (IG) was formulated in water and applied andcontrols were given equal volumes of water without IG. After seeds orbulbs showed emergence of roots, 0.1 ml of 10 mM IG in water was addedto each culture vessel for treatments and 0.1 ml of water was added toeach control. Clear plastic 500 cc containers, perforated for drainage,were filled to a depth of 10 cm with up to 900 grams of microbeads each.Initially, basal plates of bulbs were immersed 1 cm into moistened 700μm nmd silicate beads to initiate rooting. Within a week, first rootsemerged and each bulb was treated with 0.1 ml of aqueous 10 mM IG.Controls were treated with addition of 0.1 ml water to their media.After 8 h uptake of the treatments, fertigation resumed in a mannerconsistent with pH-control. In another case, 0.3 mM4-amino-phenyl-α-D-mannopyanoside (APM) was dissolved in water with 3ppm Mn as EDTA, 6 ppm Ca as EDTA. A solution of the formulation wasapplied to rooted Crocus. APM-treated plants were compared to plantsgiven identical control formulation without APM. Within five hours oftreatment and, through fertigation, thereafter, all container cultureswere regularly given equal volumes of nutribead solution. Controls wereplaced side-by-side and cultivated, likewise.

For all experiments, at 7 d to 14 d after treatment, microbeads weresaturated with water. Immediately, individual plants gently were pulledand lifted out of the water-saturated silicate microbeads by hand. Rootsof harvested plants were dipped in a full beaker of water to release thebeads from the roots, whereupon, most of the microbeads rolled off theroots and dropped to the bottom of the beaker. For paperwhites, volumesof entire roots were measured by displacement of water in glass beakers.

Clones of Botryococcus braunii Kützing var. “Ninsei” U.S. plant patentPP21091 were deposited as ATCC No. PTA-7441, and maintained by theinventor. Microbeads were inoculated with approximately 50,000 clones of“Ninsei” in 5 ml of nutrient media. Micropropagation was undertaken on“Ninsei” under sterile nutrient transfer conditions. Sterilized vesselswith injection input and drainage output ports were fashioned fromplastic parts and filled with sterilized 300 μm nmd silicate beads.Buffered pH 7 nutrient solution was injected and drained continuously,thus maintaining pH and sterility.

Light intensity was measured out of doors as reflected values directlyover bare soil as compared to sandy loam with a 1 cm layer of moist TypeA microbeads applied over the top of the soil at noon in Arizona.Sunlight was 1700 to 1800 μEin·m⁻²·sec⁻¹ at the time of measurements.Ten readings of each were taken.

Results

The various microbeads that were tested provided support for hydroponicculture of plants. Plants stood erect, anchored by their roots in thesilicate microbeads. With adequate drainage and frequent flows ofnutrient-enriched irrigation, fertigation, through 500 μm to 700 μm nmdsilicate beads, cultivation was achieved. Beads of 500 μm nmd proved tobe the most applicable for starting seeds; whereas, 700 μm nmd or largersilicate spheres were generally the best for bulbs, vegetative cuttings,and large seeds >1 cm. Aeration appeared to be adequate in our shallowcultures, that is, roots showed no symptoms of browning that would havebeen typical of hypoxic root environments. Notably, it was observed thatthe larger the beads, the longer the durations of pH-stability. Thereby,when left in water, the largest 700 μm nmd beads maintained neutralityfor the longest duration as compared to smaller beads. When startingseeds solely in 700 μm nmd silicate microbeads, maintenance of moisturein beads at the surface was critical to germination. The top 1-3 cm ofthe 10 cm total depth of the culture completely drained of water and, onlow humidity days, these upper layers of dry beads left some seedsperiodically desiccated. Thereafter, high moisture content at thesurface was maintained by raising the depth of water to match the depthof the silicate media until seeds germinated.

To accomplish non-damaging removal of the solid media, as soon as rootswere immersed in full beakers of water, microbeads rolled off of theroots and dropped to the bottom of the water vessel. A photographshowing crocus that was rooted in moist microbeads followed by therelease of microbeads from the roots is exhibited in FIG. 1 exemplifiedby comparing treatment with APM to Control. Growth of roots wasconveniently and quickly compared by lifting individual shoots up andout of the microbeads with intact roots, where the APM-treated plantshow clearly advanced productivity over Control.

Hydroponic propagation of cuttings of coleus was undertaken incontainers filled with moistened 500 μm nmd silicate microbeads, withdaily exchanges of nutrient solution, resulting in branched rootdevelopment within two weeks. Images of rooting from vegetative cuttingsin microbeads are displayed in FIG. 2, as follow: FIG. 2(A) Vegetativepropagation of cuttings of coleus in 500 μm nmd microbeads with dailyexchanges of nutribead solution, resulted in growth of adventitiousroots; and FIG. 2(B) When gently pulled out of microbeads, rootsremained intact, showing root hairs and caps by macrophotography.

Corn was cultured in 700 μm nmd beads. Clear plastic 500 cc containers,perforated for drainage, were filled to a depth of 10 cm with up to 900grams of microbeads each. Seeds were sown by immersion intobuffer-moistened 700 μm nmd silicate beads. After roots and shootsemerged, a plant was treated with 1 mM IG. After a week, its taprootgrew to 7 cm total length. In contrast, the control had a shorter 5 cmtaproot. Adventitious roots were observed in all corn grown in silicatebeads. Corn plants cultured in 700 μm nmd silicate beads with bufferednutrient solution of the present invention are exhibited in FIG. 3,wherein, control showed a 5 cm taproot, but the plant treated withindoxyl glycopyranoside, in accordance with certain embodiments,exhibited a 7 cm taproot. The corresponding dry weights of each entireplant and separated roots were as follow: control plant, 0.2 g, androots, 0.03 g; and individual IG-treated plant, 0.3, and roots, 0.04 g.

Paperwhites, were cultured for 35 d in 700 μm nmd silicate beads inclear plastic 11 cm tall 500 cc cylinders (FIG. 4A) with drainage holes.Culture vessels were each filled with up to 900 grams 700 μm nmdmicrobeads to a depth of 10 cm. Results after 10 d growth are shown inFIG. 4B, in that the control, left, showed roots up to approximately 5cm in length in a ring around the basal plate; in contrast, bulbstreated with IG, right, exhibited roots approximately 6 cm to 7 cm long.Consistent with the visual observations, 16 days after treatments,plants were lifted out a second time, showing a significant (n=6;p=0.01) difference in average root volume, as follow: Controls showed amean root volume of 30 cc per plant; whereas, IG-treated plants showed amean root volume of 37 cc per plant. Abundant availability of nutrientspermits high density culture of plants, thus, bulbs may be appressed toeach other or spaced within 1 to 5 cm apart and achieve vigorous growthpotential, as exhibited in FIG. 4C.

Generally, pretreatment of any size of microbeads with a nutrientsolution buffered to approximately pH 5 to pH 6 was beneficial andassured initiation of experiments with neutral to mildly acidic, pH 6,medium. The buffer solution is exhibited in Table 1, and consists ofmonoammonium phosphate (MAP) and monopotassium phosphate (MKP) as ameans of providing major plant nutrients, N-P-K. If the beads are to besterilized, it is best to autoclave them separately from theNKP-pretreatment solution and then to moisten them after cooling anddistribution.

TABLE 1 Buffered NPK-pretreatment Solution Sodalime silicate microbeadsare alkaline, approximately pH 9, therefore, saturation in an acidbuffer made from major plant nutrient salts are applied to neutralizethe media prior to sowing seeds. Dissolve crystals in water and apply 10minutes before utilization. 1 Liter 3 mM NH₄H₂PO₄ MAP (mw 115.03) 0.35gram 1 mM KH₂PO₄ MKP (mw 136.9) 0.14 gram

The buffered hydroponic nutrients in the buffered nutrient solution, inaccordance with the present embodiments, are disclosed in Table 2 andinclude ammonium salts to maintain buffering with ammoniacal hydrogenions contributing to acidity. Therefore, (NH₄)₂HPO₄, as bulk 35% DAP,and bulk 25% MAP, were incorporated. Chelated calcium was utilized toinsure solubility in the sodalime silicate microbead environment.

TABLE 2 Buffered Nutrient Solution The recommended water-culture mediumis designed to flow through the sodalime silicate microbead media tomaintain a pH 6 to pH 7 environment. For sterile culture, make thenutrient solution in deionized water to prevent precipitation. 1 Liter 3mM KNO₃ 0.255 gram 2 mM (NH₄)₂SO₄ 0.26 gram 0.8 mM (NH₄)₂HPO₄ 35% DAP0.30 ml 1.2 mM NH₄H₂PO₄ 25% MAP 0.552 ml Sequestar ® Multi-NutrientChelate 0.05 gram 3% Ca⁺² as Na₂EDTA 0.25 ml

Culture of “Ninsei” in 300 μm nmd silicate microbeads required frequentexchanges of sterile nutribead solution, aided by construction of amicrobead hydroponics vessel with input and output ports, exhibited inFIG. 5. The vessel was filled to a depth of approximately 2-3 cm with upto 200 grams of 300 μm nmd microbeads. The microbeads were moistened bydrip irrigation with buffered nutrient solution at a 1 ml/hour flowrate. After the microbeads stabilized at pH 7, the moist bed wasinoculated with “Ninsei.” As a result of this micropropagationtechnique, visible growth of macroscopic “Ninsei” became evident as darklayers of colonies above the output port and as a central darkcrescent-shape upon the surface of the clear microbeads, shown in FIG.5. It was evident that maintenance of neutrality by saturation of theculture medium with carbon dioxide gas prior to application of thenutrient medium to sodalime silicate beads resulted in enhancedcultivation of “Ninsei” during daylight periods. This technique clearlydemonstrated the viability of microbead media for microbes.

In order to foster sufficient flow rates and to prevent puddling 700 to5000 μm nmd silicate microbeads are recommended for the cultivation ofplants. Furthermore, silicate microbeads of 500 μm and larger diametersare generally the safest to handle.

Solar light intensities out of doors at high noon were measured directlyover substrates at 2.5 cm distance, as follow: Sandy loam, 270 to 300μEin·m⁻²·sec⁻¹; and Type A microbeads, 360 to 380 μEin·m⁻²·sec⁻¹.Silicate microbeads refracted light upward from the ground atapproximately 20% higher light intensity than sandy loam. Thissupplemental light intensity from refraction by silicate microbeadscontributed to midday wilting in vegetative cuttings of coleus when theywere placed in direct sunlight because they were cultivated incontainers filled with moist microbeads.

The main drawback of silicate microbeads stems from their raw materialssource, recycled sodalime glass, that is alkaline; however this does notpreclude utilization of the alkaline nature of sodalime to advantage.The smaller the bead is, the larger the surface area from which toextract native pH 9 alkalinity. Pretreatment of microbeads with theNPK-buffered solution and with sequestration of carbon dioxide gas bythe beads immediately prior to plantings provided a consistentenvironment for plant cultivation and overcame the alkalinity problem.The volume of buffer solution may be minimized by installation ofpH-controllers as a means of automating issuance of buffered nutribeadsolutions.

In all cases, continuous or hourly to daily input of buffered nutrientsolution through the media, when accompanied by drainage, maintainedneutrality of the sodalime silicate microbeads; and it may be possibleto further reduce the alkalinity experienced from sodalime byutilization of borosilicate microbeads and also by supplementation withcarbon dioxide gas. The beads of 700 μm nmd promoted more rapidcirculation of the buffer solution than smaller beads. In all cases andat all scales of operations, circulation by means of inflow and effluentsystems, as exemplified by the plumbed vessel shown in FIG. 5, aid inmaintenance of neutral media. For example, neutrality is maintained bycontinuous flow in of 10-100 ml nutribead solution per hour per kilogramof 700 μm nmd sodalime silicate microbeads with matching drainage out ofthe container. To prevent leakage of microbeads, an appropriately sizedgrate, sieve, filter or solid media may be required at the drainagesystem. Moreover, at bead depths greater than 8 cm, injection of airand/or elevated carbon dioxide gas and air mixtures from the bottomthrough fritted airlines may be applicable toward maintenance of oxygengas levels for healthy roots.

Industrially, as mechanical media, mixtures of various sizes of silicatebeads may be most beneficial for starting bulbs, vegetative cuttings andtransplants and comparative investigations of the effects of differentsolid media on transplant shock may elucidate possible benefits ofreducing or eliminating injury to roots. Sterile beads as media formicropropagation may be useful, where, by the installation nutrientcirculation and pH-control systems, microbeads may be utilized asinorganic replacements for agar. The morphology and hydraulicconductivity of plants is influenced by rooting media and, therefore,may further benefit from defining morphological and physiologicalresponses of plants on defined media such as microbeads.

Microbeads present features and benefits, as follow: Roots releasemicrobeads without apparent damage; moist beads provide anchoring thatsupports plants for upright shoot growth; roots may be tracked throughtransparent culture vessels; light quality may be adjusted by refractionof specific colorings; new beads generally are contaminant-free; variouscoatings added to microbeads may provide time-release and reduced dosagerequirements of nutrients, pesticides and herbicides; different sizes ofmicrobeads may be selected as appropriate while they reduce water by thevolumes they displace; and solid microbeads withstand pressure and heatfor washing, autoclave-sterilization and repeated utilization.

Silicate microbeads may prove most useful for their sequestration ofcarbon dioxide and for their potential benefits to light enhancement.

EXAMPLE 2

Plant responses to formulations of an alkyl-α-D-mannopyranose and anelectron donating-aryl-α-D-mannopyranose were consistent with preferredbinding tendencies to displace glucose from storage. Plants weremaintained in automated greenhouses controlled for temperature, lightand circulation. Environmental conditions during the course of thestudies averaged 13:11 hour L:D photoperiod, 25°:20° C. day:night and20% to 80% relative humidity. Sunlight was supplemented with electricalillumination to achieve photosynthetically active radiation levelsranging from 350 to 600 μmol photons·m⁻²·s⁻¹ at the level of thephylloplane. Solutions for treated and control plants were appliedwithin an hour, otherwise subjecting all plants to identical conditionsconsistent with good laboratory practices. Solutions applied to controlsincluded nutrients and surfactants identical to the treatment solution,but without the active compound. General supplementation of foliarformulations included the following: 10-100 mM ammonium salt; 1-6 ppmmanganese, Mn-EDTA; and 5-10 ppm calcium, Ca-EDTA. For example, foliarsolutions of 0.3 mM p-aminophenylmannopyranoside, hereafter referred toas APM, were supplemented with 23 mM ammonium sulfate, (NH₄)₂SO₄, 3 ppmMn and 6 ppm Ca; and Nutrient Control contained 23 mM (NH₄)₂SO₄, 3 ppmMn and 6 ppm Ca. The foliar concentrations of Mn and Ca were higher thanthose specified previously because of the low volumes of foliarapplications relative to hydroponic root immersion volumes, and theywere particularly effective in combination with foliar applications ofcompounds because they supported high rates of productivity in thetreated plants without phytotoxicity. Compounds for experimentationincluded the following: methyl-α-D-mannopyranoside (MeM), APM, andmethyl-α-D-glucopyranoside (MeG). All foliar solutions were formulatedwith 1 gm/liter surfactant blend consisting of 0.5 gram DowCorning Q5211dispersed into 1.5 grams BASF Pluronic L62. As a matter of course,untreated controls that foliar nutrients and wetting agents were notintroducing artifacts. The standard volume for foliar application ofexperimental treatments was 200 liters/hectare. Identical volumes offoliar spray per tray of plant cultures were applied mechanically in asingle pass. Controls were placed in the same location and givenidentical irrigation and handling as the treated plants. To compare theeffects of treatments under tightly controlled conditions, plants werecultured, harvested, cleaned and weighed as per previously describedmethods. Treated plants were statistically analyzed in comparisonsagainst controls. Each survey population held sufficient replicatesample numbers to make meaningful statistical analyses utilizing SPSS®software. Significance was determined at the 95% confidence interval(CI) of the difference. Counts of population numbers are denoted as “n”values. For experiments, radish “Cherry Bell” Raphanus sativus L., aroot crop was planted and treated.

Results

With radish, foliar treatments with formulations of 129 mM MeG,supplemented with soluble calcium, manganese and ammoniacal nitrogencompounds, consistently increased productivities over nutrient anduntreated controls. In side-by-side preliminary experiments to explorethe dose responses of α-D-glycopyranosides on radish, an effective rangeof 1 mM to 3 mM MeM and a range of 0.1 mM to 0.5 mM APM were determinedby visual analyses that showed similar growth enhancements of radish to129 mM MeG. Therefore, least concentrations were selected forstatistical experimentation; and 200 l/ha foliar 1 mM MeM or 0.3 mM APMin nutrient-supplemented formulations were applied to 5 cm tall sprouts;while, Nutrient Controls were given foliar applications of identicalsolutions without the α-D-glycopyranosides; and no foliar solutions wereapplied to untreated controls which were otherwise identicallycultivated and irrigated. For our quantification experiments, whenimprovements of root productivity over those of nutrient controls werevisibly discernible 12 d after treatment, all populations of controlsand treatments were harvested, and individual dry weights of treatmentand control populations were analyzed.

Treatments with the α-glycosides showed enhanced growth over untreatedand nutrient controls. As presented in FIG. 6, highly significant (n=72;p=0.001) improvement of growth over controls was exhibited by radishtreated with 1 mM methyl-α-D-mannopyranoside supplemented with nutrients(MeM) at 30% root weight increases over controls; moreover, significant(n=72; p=0.003) improvement of growth over controls was exhibited byradish treated with 0.3 mM amino-phenyl-α-D-mannopyranoside (APM)showing upward of approximately 20% root mean dry weight increase overcontrols.

Release of glucose from glycoprotein storage structures may besummarized from least to greatest as follow:glucopyranose<aryl-α-glucopyranose<alkyl-α-mannopyranose<electrondonating aryl-α-glycopyranoside. Therefore, based on that data, growthresponses of compounds that tightly bind in the presence of Ca and Mnwas compared. The order of active concentrations of each of thesecompounds applied for growth response, 129 mM MeG, 0.3 mM APM, and 1 mMMeM, roughly corresponded to the binding tendencies of the compounds.That is, high concentrations of alkylglucopyranoside, MeG; less ofalkylmannopyranoside; and the least concentration of arylmannopyranosidefor storage corresponded to the similarly proportioned foliar mMrequirements for significant growth responses in radish. Theexperimental measurements reported herein support the involvement ofrelease from glycoproteins in the mechanism of action of enhancedproductivity by substituted glycopyranoses. The characteristics thatsupport involvement with the mechanism action of glycopyranoses includethe following: Productivity of plants is enhanced by both α- andβ-glycopyranoses; sugar-conjugated aryl-plant growth regulators areactive, also; consistency of response is achieved in the presence of Mn;methylglucoside is transported intact; an isolated metabolite stained byninhydrin indicates the presence of a nitrogen moiety; andmethylglucopyranoside is partitioned. Chemical competition againstsubstituted sugars acts to release sugar from glycoprotein, and this isan essential process to sustain viability under conditions in which theconcentration of glucose in a cell is diminished. Competitive bindingmay be a natural mechanism for the displacement of sugars on a regularbasis, allowing energy to be rapidly reapportioned for growth as aresult of metabolism of the freed sugar unit, rather than going throughconsumptive steps involved in breakdown of starch or lipid. For example,it may be assumed that in the field, the concentration ofmethyl-β-D-glucopyranoside remains nearly constant in the plant and as aresult of midday photorespiratory depletions of the concentration ofglucose, competition for release from storage components such as lectinsby the ever-present methyl-β-D-glycopyranoside arises and glucose isrepeatedly released. To an extent, the timely releases of free glucosemay mitigate the effects of any stress cycles that cause reductions ofglucose in a plant cell. Afterward, under conditions more conducive tophotosynthesis, critical concentrations of glucose are rebuilt tosufficiently high levels that a surfeit of glucose outcompetesmethyl-β-D-glycopyranoside. This cycle may repeat itself on a dailybasis, releasing sugar at each lengthy photorespiratory event, followedby the capture of fresh sugar upon resuming photosynthesis. The higherthe quantity of glucose stored in the plant, the more capable it may beof capturing and releasing sugars to endure prolonged periods ofphotorespiration. In contrast, when exogenous chemical competitors forbinding sites are applied to plants, especially by the input ofsubstrates, such as APM, the duration of the effect may be substantiallyextended precisely because foreign compounds may be selected forcompetitive advantage of permanent bonding. On the other hand, in caseswhere a single dose of MeM is called for, then glucose would not bestored after the application of MeM, but would be directly metabolizeduntil new cells are produced.

EXAMPLE 3

Protocol for single step manufacture of a novel blend of the followingmixed poly-acetyl-D-glycopyranoses (MPG): acetyl-D-mannopyranose,di-acetyl-D-mannopyranose, tri-acetyl-D-mannopyranose,tetra-acetyl-D-mannopyranose, and penta-acetyl-D-mannopyranose.

The catalyst is novel and is comprised of potassium, manganese, andcalcium salts of acetate.

Reagents:

α-D-Mannose 180 g Glacial acetic acid 120 g Potassium acetate  59 gManganese acetate  1 g Calcium acetate  2.5 g Acetic anhydride 353 gInto a three-neck round bottom flask with stirrer on a heating mantle,insert a thermometer in one neck of the flask. Place a funnel in themiddle neck and a removable stopper for the third one. Start by placing120 grams glacial acetic acid in the round bottom flask and dissolve in59 g of potassium acetate by slowly adding crystals into the flask withstirring. Add in 1 g manganese acetate with stirring. Stir until acetatesalt crystals dissolve. Start adding mannose with continuous stirring.Maintain the temperature at 70 to 72° C. Pump in the acetic anhydride atthe rate of 2 grams per minute. This slow rate of addition keeps thetemperature under control and allows the even distribution of acetategroups. The process may take around 2 hours. Add 2 grams of calciumacetate to the other catalysts. Strip off excess acetic acid in a rotaryevaporator.

It important to note that pentaacetylmannopyranose must be dissolved ina water-miscible organic solvent prior to aqueous solution. The reactionis driven to full acyl-substitution at temperatures above 80-100° duringsynthesis or if sulfuric acid is added.

Daltons Pentaacetyl-D-mannopyranose 390.3 Tetraacetyl-D-mannopyranose348.3 Triacetyl-D-mannopyranose 306.3 Diacetyl-D-mannopyranose 264.3Acetyl-D-mannopyranose 222.3

Catalysts:

-   Potassium acetate-   Calcium acetate-   Manganese acetate-   The process yielded 60% MPG.

Indications from high water solubility and chromatography are that theblend was approximately 80% tetraacyl-, 10% triacyl-, 8% diacyl-, and 2%acyl-D-mannopyranoses. There was, most likely, a trace ofpentaacyl-α-D-mannopyranose, but it did not register in thechromatograph.

The final formulation for application to roots may includesupplementation with 25 mM to 100 mM ammoniacal nitrogen, such asammonium salts or urea, or 5% to 25% available nitrogen in theconcentrate. The final formulation for application to shoots may includesupplementation with 25 mM to 100 mM ammonical nitrogen, as well as asuitable agricultural surfactant such as 2 to 6 g/L random blockcopolymer (Pluronic L92) blended with 0.7 to 2 g/L polysiloxane wettingagent such as Dow Corning Q-5211. The foliar application rate of MPG at20 gallons per acre is in the range of 0.1 gram per liter to 100 gramsper liter, with preferred rates in the range of 0.3 grams/liter to 30grams per liter, and most highly preferred rates in the range of 0.4 g/Lto 10 g/L. The root application rate of MPG at 5 ml/plant is in therange of 0.001 to 100 g/plant.

EXAMPLE 4

Plant responses to formulations and systems of photosafeners andsodalime silicate microbeads were improved by sequestration of carbondioxide gas by the alkaline sodalime substrate in which the plants werecultivated. Sodalime silicate microbeads were utilized to fill a 0.5 mtall plastic cylinder and the column was saturated with water. Through aglass bubbler inserted at the bottom of the cylinder, 5% carbon dioxidegas was injected into the microbeads. Automated pH-control was achievedby programmed injection of carbon dioxide gas when the medium rose to pH7.5 and above. Alkaline qualities of sodalime silicate microbeads were,thus, exploited to improve distribution and sequestration of carbondioxide by the sodalime silicate hydroponic support medium because thecarbon dioxide gas is captured by the alkaline medium. The culture ofplants in microbeads may be achieved by incorporating a system ofbubbling 3% to 100% carbon dioxide gas into the bed of microbeads formaintaining pH 6-7, which provide appropriate environments for plants.After the initial saturative exposure, water may be replaced andaccompanied with continuous flow through of plant nutrients, includingelevated levels of available nitrogen when supplying carbon dioxide gasfor temporal sequestration by microbeads that may be further sequesteredby photosynthesis.

EXAMPLE 5

Glycosides improve productivity and they are transported in plants fromroot to shoot and from shoot to root. Furthermore, formulations ofpolyalkylglycoside and mixed polyacylglycopyranose (MPG) are more potentthan MeG. α-Glycosides have higher binding affinities to lectins overβ-glycosides. Consistent with specific affinities of lectins, highestpotencies are demonstrated for α-mannosides.

2. Materials and Methods

Plants were cultured in research facilities and consistency of responseto treatments was achieved by supplementation with chelated calcium andmanganese. All plants were regularly given modified Hoaglandwater-culture nutrients. Foliar solutions included phytoblandsurfactants, but formulas for roots did not. Controls were placed in thesame location and all plants were given the same irrigation,fertilizers, and handling, but without the experimental compounds.Plants were matched to controls and treated within a week of emergenceof cotyledon and true leaves. The performance of compounds was evaluatedby comparing means of individual dry weights of shoots and roots.Statistics applied two-tailed Student's t-test with p-values significantwithin 95% confidence intervals. Counts of populations are “n” valuesand standard error is denoted “±SE.” Specialty chemicals included thefollowing: tetramethyl-β-D-glucoside (TMG); tetraacetyl-D-glucopyranose(TAG); pentaacetyl-α-D-mannopyranose (MP); p-amino-phenyl-α-D-mannoside(APM); methyl-α-D-mannoside (MeM) and methylglucoside (MeG). MPG wassynthesized. 2,3,4,6-tetra-O-acetyl-D-mannopyranose (αβ) was utilized.As required, MP and APM were dissolved in a lower aliphatic alcoholprior to dilution in aqueous media.

Assay—Radish seedlings were treated with α-mannosides after emergence ofradicles. Seedlings were matched and transferred to Nutrient Control ortreatment solutions. Assays were maintained under environmentalconditions as follow: Photosynthetically active radiation 100μEin·m⁻²·sec⁻¹, diel cycle of 16:8 h light:dark, 26:26° C.

Glass microbeads—μBeads were obtained with the following specifications:Nominal modal diameters 500-700 μm; density 2.5 g/cc; pH 9; and sodalimeglass. Reflected light intensity (I) was measured out-of-doors directlyover bare sandy loam as compared to 1 cm layer of μBeads where solar Iwas in the range of 1700 to 1800 μEin·m⁻²·sec⁻¹. For drainage,containers were perforated with holes smaller than the μBeads. After >8h uptake of treatments, fertigation resumed in a manner consistent withpH-control and cultures were regularly given equal volumes of nutribeadsolution. Controls were placed side-by-side and cultivated likewise.Basal plates of bulbs were immersed into moistened 700 μm μBeads toinitiate rooting, after which they were treated. For photography, μBeadswere saturated with water and individual plants were manually liftedout. When roots were dipped in a beaker of water, most μBeads droppedoff. Representative plants were selected visually from amongexperimental populations for macrophotography. To avoid injury fromdehydration, plants were photographed within a minute and returned towater.

3. Results

Experiments on radish were undertaken to determine ranges of effectivedoses. αβ-TAM was compared to α-MP. Within one day of exposure to 1 mMTAM or 100 μM MP, early greening of some of the seedlings was visuallydiscernible from the Nutrient Control. After 48 h, seedlings treated to1 mM TAM or to 100 μM MP showed advanced growth responses as compared tothe nutrient Control. Application of 1 mM TAM to radish seedlingsresulted in statistically significant enhancement of mean dry weight(n=41; 8.8 mg) of whole plants over mean dry weight of the nutrientControl (n=41; 7.4 mg; p=0.002). At a lower dose, treatment with 100 μMTAM resulted in no significant difference of mean dry weight (n=41; 8.1mg; p=0.11) from the nutrient Control. Application of MP to radishseedlings resulted in significant enhancement of mean dry weight (n=41;8.2 mg) of whole plants over the mean dry weight of the nutrient Control(n=41; 7.4 mg; p=0.05). Therefore, α-MP showed higher potency than themixed anomers at these effective doses of 100 μM MP and 1 mM TAM whencompared to the nutrient control.

Exposure of radish seedlings to 500 μM MeM resulted in notable greeningof some plants within 36 h. Rapid responses were observed andexemplified by visual comparisons of treated and control radish, shownin FIG. 7. In one day, treatments with 500 μM MeM showed longer rootsand larger expansion of cotyledon leaves as compared to the NutrientControl. After 48 h, treatments with 25 μM to 500 μM MeM showed advancedgrowth responses as compared to Nutrient Control, roots and shootsshowing robust enhancement of growth over the nutrient Control, asfollow: Application of 500 μM MeM to radish sprouts resulted instatistically significant 11% enhancement of mean dry weight (n=10; 10.3mg) of whole plants over nutrient control mean dry weight (n=10; 7.9 mg;p=0.000). 50 μM MeM resulted in significant 11% enhancement of mean dryweight (n=10; 11 mg) over mean dry weight of the Nutrient Control (n=10;9.9 mg; p=0.03). Results of dosing radish roots with 25 μM and 100 μMMeM are graphically summarized in FIG. 8, wherein treatment with 100 μMMeM resulted in a highly significant 17% enhancement of mean dry weight(n=15; 10.9 mg) over the mean dry weight of the Nutrient Control (n=35;8.7 mg; p=0.003); and treatment with 25 μM MeM resulted in a significant12% enhancement of mean dry weight (n=20; 10 mg) over mean dry weight ofthe Nutrient Control (n=35; 8.7 mg; p=0.03.

Immersion of radish sprouts in 100 μM p-amino-phenyl-α-D-mannoside (APM)resulted in a statistically significant 10% increase of mean dry weight(n=10; 11 mg) over the nutrient control (n=10; 9.9 mg; p=0.01). Resultsof exposure of radish roots to 10 μM and 5 μM APM are graphicallysummarized in FIG. 9. Hydroponic culture of radish sprouts with 10 μMAPM in nutrient solution resulted in a significant 13% increase of meandry weight (n=20; 10.3 mg) over nutrient control (n=40; 8.7 mg; p=0.01);but, the mean dry weight of 5 μM APM (n=20; 9.4 mg) was notsignificantly different from that of the Nutrient Control (n=40; 8.7 mg;p=0.06. Representative selections from the populations of thisexperiment are exhibited in FIG. 10 for which a radish germling treatedwith 10 μM APM, right, showed longer roots and larger expansion ofcotyledon leaves as compared to the Nutrient Control, left.

Aqueous penta-acetyl-α-D-mannopyranose has high potency characteristicsof α-mannoside and, thus, enhanced growth resulted from treatments, asfollow: Range, 1 ppm to 1000 ppm; preferred range, 8 ppm to 80 ppm;dissolve in water-miscible organic solvent, such as methanol, ethanol,and/or isopropanol; dilute in aqueous solution in the presence of thedivalent cations, 0.5-12 ppm Mn⁺² and 1-50 ppm Ca⁺².

Glass Microbeads: The various μBeads provided support for hydroponicculture of plants. Aeration appeared to be adequate in our containercultures.

Safety: Handling μBeads must be performed according to protocols thatinclude reviews of Material Safety Data Sheets prior to experimentation.If spilled, these glass spheres are slippery underfoot and must bepicked up immediately with a vacuum cleaner. Bearing in mind that glassis over twice as dense as water, when lifting a full sack or bucket ofμBeads, take precautions to preserve healthy backs by requestingassistance. For laboratory utilization, sterilize μBeads separately fromliquids, preferably by heating the dry glass in 200° C. ovens overnight.Allow several hours for both μBeads and sterile aqueous solutions tocool to room temperature. Moisten μBeads only after cooling to <40° C.to prevent bumping. Eruptions of wet μBeads in an autoclave may damagevalves, controls, glassware, and instrumentation. Avoid touching μBeadsto mucous membranes and eyes. Wear eye protection. Don a dust mask toprevent inhalation of μBeads and glass dust.

Refractive Index: In kilns, glass beads are melted to form clear glassspheres with highly polished surfaces. Each μBead is a micro-lens thatrefracts light. Moreover, diffuse reflection of light across the surfaceof a μBead may send a fraction of the light in all directions. Light maybe directed according to the index of refraction of the glass from whichμBeads are manufactured. For example, a μBead with a high index ofrefraction exhibits reflex reflectivity, sending light back toward itssource. In contrast, a μBead with a lower index of refraction may send abeam at a right angle to the incoming ray. In FIGS. 11A and 11B,theoretical paths of light through a μBead of high index of refraction,˜1.9, are compared to a μBead with a lower index of refraction. ForFIGS. 11A and 11B, a μBead with a high index of refraction,approximately 1.9, sends light back in the general direction of itssource, top, in a phenomenon known as reflex reflectivity. A μBead witha lower index of refraction, approximately 1.5, may send light out atapproximately a right angle to its approach, bottom. In FIGS. 11A and11B, the symbol for a point source of light is a triangle in a box,labeled, “Beam of Light;” The circle labeled “Glass Microbead”represents a single μBead; and “Refraction” of a beam of light throughthe μBead follows the direction of the linear black arrows. Underenvironments with diffuse lighting, a μBead with a lower index ofrefraction may be a practical consideration. The diagram is portrayed intwo dimensions, but refraction by broadly dispersed μBeads isthree-dimensional (3D). Solar illumination is diffuse, a contiguouslayer of μBeads refracting spherically in all directions, thus, therefraction of sunlight is exhibited in FIG. 12 in which an aurasurrounds the 16 mm wide-angle lens of the handheld camera at the centerand approximately 15-30 cm above the dome of light. Out of doors,measurements of intensities directly over substrates at 2.5 cm distancewere as follow: Above sandy loam, 270 to 300 μEin·m⁻²·s⁻¹ and overμBeads, 360 to 380 Ein·m⁻²·s⁻¹; sunlight refracted upward from theground at approximately 20% higher light intensity than sandy loam. Theadditional light intensity from surface refraction may induce middaywilting for plants placed under direct sunlight and cultivated in μBeadsthat may be corrected by preparing plants with applications ofglycosides.

4. Discussion

The raw material source, recycled sodalime glass, is alkaline;therefore, the smaller the μBead, the larger the relative surface areafrom which to extract native alkalinity. As pH-stability was the primaryconsideration, it became evident that the largest μBeads would be thepreferred media for green plants. Treatment of μBeads with nutribeadsolution overcame the alkalinity problem while providing a bufferedenvironment for cultivation. Continuous fertigation is a means ofstabilizing the medium; and, ideally, automated pH controllers may beimplemented to efficiently meter flow rates in a manner that permitshigh density planting. As well, dense cultivation is applicable toprotistans where frequent flow through of a pH-adjusted nutribeadsolution is matched by even drainage.

Application of μBeads to crops entails broadcasting a shallow 0.4-10 mmlayer over the ground to enhance solar light intensity. As the index ofrefraction may be specified to direct light at different angles, μBeadsof a lower index of refraction may be useful to start crops at subpolarlatitudes during seasons for which the angle of solar illumination islow and bending light to a wider angle may distribute illuminationadvantageously. The application of μBeads in conjunction with glycosideformulations may be requisite to the vigorous growth of plants exposedto saturated-I by displacement of sugars from the protein complex of TheLectin Cycle of FIG. 13.

The results of current investigations are consistent with highspecificity and binding affinities of mannosides to lectins, thecorresponding potencies indicative of their tendencies towardproportionally higher orders of binding to lectins than for glucosides.A case in point, the lectin from Canavalia ensiformis, concanavalin A(con A), specifies α-trimannoside.

The following are example of specific formulations and methods accordingto certain embodiments, which advantageously may be employed to treatplants and to enhance growth in plants to increase displacement ofglucose from storage in plants. The following exemplary formulations areintended to provide further guidance to those skilled in the art, and donot represent an exhaustive listing of formulations.

EXAMPLE 6 Application of Beads to Plant Containers:

The top surfaces of black plastic 9-well trays were coated by sprayingon silver paint and allowed to dry overnight. A second application ofclear coat paint was applied to 0.35 mm dry depth. While the clearbinder was wet, a 700 μm layer of 700 μm microbeads was distributed tothe binder. The 700 μm silicate beads adhered to the top surface of theplanter tray and resulted in refraction of 20% increased light intensityover the untreated black tray surface, as shown in FIG. 15.Incorporation of microbeads to the top surfaces of plastic multiwellflats for plants significantly enhanced sunlight intensity up to plants.The microbead-coated top rim is brighter from reflex reflectivity(right) than a similar untreated flat (left). A wash of a quarter volumeof buffered solution of 1 mM monopotassium phosphate and 3 mMmonoammonium phosphate over microbeads was dispensed over trays andallowed to drain. Planter trays were filled with soil-less medium andplants were cultivated by supplementation with the above safenerformulation.

The same method may be applied to plant containers of all sizes andmaterials, such as ceramic as shown in FIG. 16, wood, fiberglass,plastic, and the like, wherein, light reflecting and/or refractingmembers such as microbeads are similarly adhered, preferably to anysurface of the container that remains exposed to artificial and/ornatural light during normal use, such as the top surface.

FIG. 16 illustrates binding microbeads to the top surfaces of plantersenhanced sunlight intensity to plants. Clear adhesive was applied as aprecoat to the rim of a 7″ ceramic pot with celadon glaze. The pre-coatwas applied to raise the microbeads off of the surface of the glaze toavoid refraction of background colors. After drying, a second 350 μmcoat of clear adhesive was sprayed onto the rim as the binder for alayer of 700 μm glass microbeads. The microbead-coated rim of potclearly is brighter (right) than a similar celadon glazed pot (left),demonstrating reflex reflectivity of the microbeads. Scale bar, 30 cm.

Application of Beads to Plastic Film:

Cultivation of outdoor field crops, such as strawberries, utilizesrow-long strips of polypropylene film as plastic mulch and as covers.Thus, this method is applicable to plastic substrates for microbeadsincluding, Mylar and other polyesters, PVC, Acetates, HDPE, LDPE, PET,Optical polymer film, UV and IR block plastics, recycled plastics, clingPVC, Shrink films, and clear polymer films and rigid structures.

Polypropylene may be selected from the following range ofspecifications:

Mulch Type Mulch film with holes; Mulch film without holes FilmPolyethylene Colors Transparent, black, yellow, black & white, silver &black Width 95, 100, 120, 135, 150, 180, 200, 210 cm Thickness 0.02,0.03, 0.05, 0.06, 0.15 mm Sizes of Holes 10, 20, 45, 60, 80 mm PackageRoll, bag

Prior to rolling the polypropylene, the film is coated withglass/plastic adhesive to 50 μm dry depth, and while the binder is wet,a single 100 μm layer of 100 μm microbeads is applied. After the binderis cured, the film is rolled in preparation for installation in thefield application as light enhancing plastic substrate for all plantsrequiring improved ambient light.

Application of Beads to Enclosed Structures:

Cultivation of plants in greenhouses and all other types of plantcultivation enclosures utilize coverings that reduce the entry of light.Superficial structures of enclosures may be coated with glass microbeadsto enhance light to the plant leaves by refraction. For example, areflecting wall, such as the bottom 3-12 feet height of eastern walls ofa housing, may be coated with microbeads to refract light from thesetting sun; or conversely, microbeads may coat the western walls of ahousing to enhance light from sunrise. On existing structures, suitabletransparent binders that are compatible with the wall surface andmicrobeads are first applied to a “refracting wall” and the glassmicrobeads are applied with air pressure to adhere to the wet adhesive.For refracting walls, a 300 μm layer of 300 μm microbeads is applied toa 150 μm adhesive coat.

Benches, tables and countertops on which plants may be temporarily orpermanently positioned, such as in a suitable container, may similarlybe coated with a single layer of 100-700 μm microbeads. Where thesurface is originally colored darkly, such as black, pre-coating withwhite or silver will enhance the reflex reflectivity.

All infrastructural surfaces of an enclosure for plant cultivation maybe embedded with microbeads prior to construction or installation byadhesion or embedding microbeads during curing or baking of the surfacemounting. Particularly, in the case of rigid plastic infrastructures,100-700 μm microbeads may be embedded into the surface while the plasticis approximately at its melting point. For example, a rigid plasticnursery table top at injection molding temperature is impressed with a700 μm layer of 700 μm microbeads for reflex reflectivity of light fromthe table top to plants above it when installed in the nursery. Thismethod is also applicable to table legs and premolded flooring tomaximize reflex reflectivity. As shown in FIG. 17, incorporation ofmicrobeads into the polyethylene film walls of a greenhousesignificantly enhanced sunlight intensity to plants. The photograph ofFIG. 17 was taken against a non-reflective black background, therefore,reflected light was attributable to the greenhouse film and its embeddedmicrobeads. A 350 μm coat of clear binder was sprayed onto half a sheetof 6 mil polyethylene greenhouse film; onto which a layer of 700 μmglass microbeads was applied before the adhesive was cured. Themicrobead-coated section of the film exhibited reflex reflectivity,showing more brightly than the area of the same sheet that was leftuntreated, demonstrating reflex reflectivity of the microbeads adheringto a wall of a greenhouse.

EXAMPLE 7 Exemplary Mannoside-Ca-Mn Kit

Formulated for foliar delivery of divalent cation nutrients.

Total Nitrogen (N) Range 1-15% Preferred 6.0% 6.0% Nitrate NitrogenCalcium (Ca) Range 1-12% Preferred 6.0% 6.0% Water Soluble DivalentCalcium Manganese (Mn)Range 0.5% to 8% Preferred 5% 5.0% Water SolubleDivalent Manganese Mannitol Range 1-30% Preferred 5%

Derived from Calcium Nitrate and Manganese Nitrate.

General Information Vegetables, Fruit Trees & Field Crops

Apply 0.5-5 quarts per acre per application throughout the growingseason. At least 3 applications are recommended. More frequentapplications at 1-2 quarts per acre may be needed to correctdeficiencies.

Ornamental Crops

Apply 0.5-1 quart per 100 gallons water. Cover foliage thoroughly topoint of runoff.

Soil Application

May be applied via drip or sprinkler irrigation at a rate of 1 to 5quarts per acre. Do not apply phosphate-based fertilizers during thesame irrigation cycle.

Mixing Instructions

Put ⅓ to ⅔ of total desired water volume in tank. Add pesticides ifrequired and agitate until thoroughly mixed. Add adjuvant or supplementif needed and agitate until thoroughly mixed. Add desired amount andagitate until thoroughly mixed. Fill tank with remainder of desiredwater. A jar test is a good field practice for evaluating compatibilityof multiple chemical mixtures. Caution: Pre-check compatibility withchemical mixtures and high phosphate and alkaline (high pH) solutions.Avoid tank mixing with alkaline solutions. The formula may effectivelybe applied with many agricultural chemicals. For unfamiliar tank mixcombinations sufficient evaluation to determine efficacy and crop safetymay be warranted. Use a minimum 10 gallons of water per acre with groundspray equipment and a minimum of 2 gallons for aerial application.Optimum rate of application will vary depending on your soil propertiessuch as soil pH, organic matter content, soil texture, weatherconditions, season, general crop health and species. For best results,follow soil test or plant analysis recommendation.

EXAMPLE 8

Temporal applications of silicate beads may be applied to row crops outof doors in narrow strips along the base of germlings. After germinationof seeds, for example, of lettuce, a 700 μm depth strip, 1″ to 36″ wide,of 700 μm microbeads is distributed over the center of the row ofsprouts for reflex reflectivity of light from the ground level up tofoliage.

EXAMPLE 9

Shaded areas of outdoor turfgrass fields present problems of matchingtheir qualities to turf in sunny fields. Application of silicatemicrobeads within the canopy of turf enhanced the supply of sunlight forphotosynthetic processes in shady spots through reflex reflectivity ofthe beads. Application of one layer of 500-700 micron size beads in theturf canopy was limited to the site specific shaded turf of golf greensevery 1 to 2 weeks while the turf plants were actively growing. Repeatedapplications throughout growing seasons of either cool or warm seasonturf varieties insured continuous turf growth using the followingprotocols: Field applications of silicate beads were applied to turf ona golf course by broadcasting a layer of 700 μm microbeads for spottreatment of shaded areas to gain reflex reflectivity for solar lightenhancement. Broadcast of microbeads was particularly effectiveapproximately 5-15 days after sowing, when applied with emergence offirst blades of grass. A 700 μm deep top dressing of microbeads isdistributed over 1000 sq ft of substrate for reflex reflectivity oflight from the surface up to grass blades. The day before microbead topdressing, turf may be photosafened by treatment at the rate of 75gallons/acre with the following mannoside formulation:

Dilute into 75 Gallons Water

Compound Preferred Range (gram) KNO₃ 20 1-1000 CaNO₃ 5 1-1000 (NH₄)₂SO₄8 1-100  1.3 mM KH₂PO₄ MKP 8, pH 6 1-80 (pH 5-pH 6) 0.9 mM NH₂HPO₄ DAP5, pH 6 1-80 (pH 5-pH 6) Fe-HeEDTA 0.5 0.1-5    Mn-EDTA 0.3 0.1-3    500μM Methyl-α-D-Mannoside 7.3 3-1000

EXAMPLE 10

Treatments of seeds of agricultural plants with mannosides aresupplemented with soluble divalent cations. Seed treatment is achievedby priming with complete mannosides formulations or by seed coating. Anexemplary seed coat formulation is as follows:

Methyl-α-D-glucoside   1 gram Manganese-EDTA, disodium salt   5 μgCalcium nitrate 0.5 gram Monoammonium phosphate 0.1 gram

Powder finely and mix the above compounds to homogeneity. Dust 500lettuce seeds to coat with the above mixture prior to planting. Sowseeds during planting season as appropriate to designated zone.

Treatment of seeds and seedlings by aqueous solutions is exemplified bymannosides supplemented with soluble divalent cations in completemannosides formulations. Coordinated treatment of seeds with glassmicrobeads is demonstrated. Benefits of such exemplary seed primingmethods are as follows: Germination and early growth of radish (Raphanussativus L., cultivar “Cherry Bell”) and Swiss Chard (Beta vulgarissubspecies cicla L., cultivar “Fordhook® Giant”) were tested forresponse to α-mannosides supplemented with Ca² ⁺and/or Mn²⁺. Rapidassays of radish seed germination and growth used hydroponic cultureswith no solid medium; longer experiments with Swiss Chard used a 2-5 mmsubstratum of 700 μm diameter glass microbeads. Neutralization of glassmicrobeads may be undertaken with dilute mildly acidic solution titratedto pH 6; for example, with mineral acids such as hydrochloric acid,sulfuric acid, nitric acid, and the like; organic acids such as uronic,citric, malic, lactic, salicylic, ascorbic, succinic, oxaloacetic,ketoglutaric, fumaric acids, and amino acids, and the like; artificialbiological buffering agents such as TRIS, BIS TRIS, MES, MOPS, HEPES,and the like; fertilizers; and most preferably, phosphates; and the mosthighly preferred compounds are combinations of compounds in a pH6-buffer that provide major nutrients for plants, such as MAP with DKPor DAP with MKP; and the like. When test medium was added, the glassmicrobeads formed an even layer, drawing liquid to the surface bycapillary action. Seeds were examined to exclude aberrantly large,small, or damaged seeds, and were placed on the surface of thesubstratum. For experiments using post-germination seedlings, seeds weregerminated in deionized water prior to exposure to nutrient media. Aseed with an emerged radicle >1 mm was recorded as germinated, andgerminated seeds were counted daily, until 95% germination. There was novisible evidence of either desiccation or waterlogging effects. Glassmicrobeads were removed by immersion and agitation in water, or manuallywith fine forceps. Harvested plants were oven-dried to determine dryweight. Treatment and control solutions were prepared by dissolvingnutrients in deionized ultrapure water.

Growth media were based on omission or inclusion of glycosides andtargeted divalent cations. Triose is the abbreviation for α-1,3-α-1,6mannotriose) and MEM is methyl-α-D-mannoside. Terminology used hereinindicates the omission or inclusion of nutrients: 000=control mediumwith no glycoside, Ca²⁺ or Mn²⁺; MeM00=medium with MeM, but no Ca²⁺ orMn²⁺; MeMCa0=medium with MeM and Ca²⁺, but no Mn²⁺, 0 CaMn=medium withno MeM, but with Ca²⁺+Mn²⁺; and so on. Similar terminology is used formedia containing triose. Results cited are means±SE. Mean values fordifferent treatments were compared using Student's t-test (two-tailed).Differences were considered significant at p≤0.05.

Results

Post-germination radish seedlings grown in complete medium with 500 mMmethyl-α-D-mannoside, Ca²⁺ and Mn²⁺ (500MeMCaMn) exhibited discernibledifferences from seedlings grown in media lacking one or more of thosecomponents. Plants treated with 500MeMCaMn showed the earliestpigmentation and had upright tall shoots and robust roots with taprootsand healthy white root hairs. In contrast, plants grown in media lackingCa²⁺ had thin, elongated roots, and plants grown in media lacking Mn²⁺had short, thick roots and shoots. Radish seedlings grown for 2 d in500MeMCaMn had significantly higher mean dry weight than plants grown inmedia lacking one or more components. Addition of MeM alone, or of Ca²⁺and Mn²⁺ with no MeM, had no significant effect on plant growth. Radishseedlings grown for 3 d on media with and without 100 μM MeM, Ca²⁺, orMn²⁺ showed nutrient omission effects similar to those observed inshorter experiments using 500MeM. Yields were highest for the completemedium (100MeMCaMn at 10±0.3 mg, n=36) and significantly lower for mediawith one or more omissions (0CaMn, 9±0.3 mg, p=0.04; MeMOMn, 9±0.2 mg,p=0.01; n=36 for each treatment). When radish seeds were germinated inthe same medium that subsequent seedling growth occurred in, completemedium produced significantly greater shoot dry weights than mediumlacking Ca²⁺ (8±0.2 mg and 7±0.2 mg, respectively, n=50 for eachtreatment). Radish seedlings cultivated on medium containing only one ofthe divalent cations showed consistent morphological differences:seedlings lacking Mn²⁺ had short, stout roots, while seedlings omittingCa²⁺ had long, thin roots. Measurement of root length after 3 days ofgrowth on various media confirmed these differences. Roots of seedlingsgrown without MeM or Mn²⁺ were significantly shorter than roots ofseedlings grown in complete medium or without Ca²⁺. When radish seedswere germinated in the same medium that subsequent seedling growthoccurred in, complete medium produced significantly greater root meandry weight than medium lacking Ca²⁺ (1.8±0.07 mg and 1.5±0.06 mg,respectively, n=50 for each treatment). Swiss Chard seeds are slower togerminate than radish and were used to examine effects of nutrientomission on germination, first, by counting emergence of radicles untilall seeds in one treatment had germinated. Of 100 seeds sown ontocomplete medium (100MeMCaMn), daily counts were 0, 19, 60, 75, 80, and100; as compared to counts of 0, 13, 41, 58, 63, and 84, when sown onmedium lacking MeM. Thus, not only did complete 100MeMCaMn mediumproduce higher daily counts than 0CaMn, the mean count was higher (56 vs43). Early germination also resulted in greater shoot height and rootlengths that significantly enhanced whole plant dry weight, with100MeMCaMn=1.5±0.04 mg, 0CaMn=1.4±0.06 mg, n=60 for each treatment,after 7 days of seedling growth. Germination rates of Swiss Chard seedsin media containing 100 μM MeM were consistently higher than rates inmedia without the glycoside. Seeds in medium with MeM and Mn²⁺, butlacking Ca²⁺, exhibited a higher initial germination rate than seeds incomplete medium or in medium lacking Mn²⁺, but after the first fourdays, rates were similar for all three media containing MeM. Thus, as inseedling root growth, the effect of glycoside on germination, i.e., rootemergence, was optimized in the presence of Mn²⁺ without Ca²⁺, but notin the presence of Ca²⁺ without Mn²⁺. Trisaccharides with terminalα-mannosyl ligands are specific to mannose-binding lectins and have thehighest binding affinities. To examine effects of low concentrations onseedling growth, 60 radish seedlings were cultured in 30 ml media, eachcontaining 0, 0.3, 1 or 10 μM triose with Mn²⁺ and Ca²⁺. After 1 day,treatments were decanted and replaced with DI H₂O. On the second day,mean dry weights were significantly greater for seedlings grown incomplete media at 0.3, 1 or 10 μM triose concentrations than forseedlings grown in medium with no triose. Seedlings grown with 1 μMtriose, but lacking Ca²⁺, were comparable to seedlings grown with notriose. No growth enhancement was observed with less than 0.3 μM trioseand responses to treatments with complete 1 μM triose were visuallydiscernible within two days. The effect of triose on plant growth ispotent and requires both divalent cations. Seed priming with α-mannosidein combination with Ca⁻² and Mn⁺² resulted in significant enhancement ofseed germination and seedling growth, compared to treatments lacking oneor more of those components. Without both divalent cations, α-mannosideshad no significant effect on seedling yields. However, medium containingα-mannoside and Mn⁺² accelerated seed germination and enhanced rootgrowth in the absence of Ca⁺².

EXAMPLE 11

Protocol for a single step novel blend pentaacetyl-α-D-mannopyranose forplants. The α-mannoside, pentaacetyl-α-D-mannopyranose, exhibits potentactivity when formulated with soluble manganese and calcium divalentcations. A method for manufacturing by means of a novel catalystcomprised of zinc, manganese and calcium salts of chloride, is provided:Add 0.4 g anhydrous zinc chloride, 0.1 g anhydrous manganese chloride,and 0.1 g anhydrous calcium chloride in 12 ml acetic anhydride and 2.0 ganhydrous mannose into a 100-ml round bottom boiling flask. Add aboiling stone, fit the flask with a condenser and heat the flask with anelectric mantel until the contents start to boil. Turn the heat offuntil the exothermic reaction stops and then, with about 2 more minutesof heating, boil the mixture. Pour the hot solution with good stirringinto about 250 mL of a mixture of water and ice until the suspension issolidified. Collect the solid by filtration or centrifugation.

Although specific features are described with respect one example andnot others, This is for convenience only as some feature of onedescribed example may be combined with one or more of the other examplesin accordance the methods and formulations disclosed herein.

What is claimed is:
 1. A container for growing a plant, comprising atleast one container wall having a surface, said wall having one or morelight reflective and/or refractive members attached.
 2. The container ofclaim 1, wherein said one or more light reflective and/or refractivemembers comprise one or more silicate microbeads that are buffered toneutrality.
 3. The container of claim 1, wherein said one or more lightreflecting and light refracting members comprises silicate microbeads.4. The container of claim 1, wherein said one or more light reflectiveand refractive members are silicate microbeads cultivated with microbes.5. The container of claim 1, wherein said one or more light reflectiveand/or refractive members are silicate microbeads coated withmicrobials.
 6. The container of claim 1, wherein said container containsa plant, and wherein said one or more light reflective and/or refractivemembers are positioned in said container to redistribute light towardsaid plant, and are present in an amount effective to cause harmfullight saturation of said plant.
 7. The container of claim 6, whereinsaid container further contains one or more glycopyranosidic compoundspresent in an amount effective to safen and protect said plant from saidharmful effects of light saturation.
 8. The container of claim 7,wherein said glycopyranosidic compounds are one or morealkyl-α-D-mannosides.
 9. The container of claim 8, wherein said one ormore alkyl-α-D-mannosides is present in said container in an amount of 1to 10,000 ppm.
 10. The container of claim 7, wherein said one or moreglycopyranosidic compounds is selected from the group consisting ofalkyl-α-D-mannosides, methyl-α-D-mannoside, ethyl-α-D-mannosides,propyl-α-D-mannoside; poly-alkyl-α-D-mannosides,tetra-alkyl-α-D-mannosides, tetra-methyl-α-D-mannosides,tetra-ethyl-α-D-mannosides, tetra-propyl-α-D-mannosides;poly-O-acyl-D-mannopyranoses, poly-O-acetyl-D-mannopyranoses,tetra-O-acetyl-D-mannopyranoses, penta-acyl-α-D-mannosides,penta-acetyl-α-D-mannopyranoses; aryl-α-D-mannosides,phenyl-α-D-mannopyranosides, aminophenyl-α-D-mannopyranoside,aminophenylmannopyranoside, aminophenylxyloside,aminophenylfructofuranoside, indoxyl-α-D-mannopyranosides; aryl, alkyl-and/or aryl-polymannosides; and (glycopyranosyl)_(n) glycopyranosides,where n=1-4.
 11. The container of claim 7, wherein said glycopyranosidiccompounds are one or more methyl-α-D-mannosides.
 12. The container ofclaim 7, wherein said container further contains soluble manganese andcalcium.
 13. The container of claim 12, wherein said soluble manganeseis present in said container in an amount of 0.5-12 ppm Mn⁺² and saidsoluble calcium is present in said container in an amount of 1-100 ppmCa⁺².